scale_atmos_dyn_common Module Reference

module Atmosphere / Dynamics common More...

Functions/Subroutines
subroutine, public	atmos_dyn_filter_setup (num_diff, num_diff_q, CDZ, CDX, CDY, FDZ, FDX, FDY)
	Setup. More...
subroutine, public	atmos_dyn_numfilter_coef (num_diff, DENS, MOMZ, MOMX, MOMY, RHOT, CDZ, CDX, CDY, FDZ, FDX, FDY, DT, REF_dens, REF_pott, ND_COEF, ND_ORDER, ND_SFC_FACT, ND_USE_RS)
	Calc coefficient of numerical filter. More...
subroutine, public	atmos_dyn_numfilter_coef_q (num_diff_q, DENS, QTRC, CDZ, CDX, CDY, dt, REF_qv, iq, ND_COEF, ND_ORDER, ND_SFC_FACT, ND_USE_RS)
	Calc coefficient of numerical filter. More...
subroutine, public	atmos_dyn_filter_tend (phi_t, phi, rdz, rdx, rdy, KO, IO, JO)
subroutine, public	atmos_dyn_copy_boundary (DENS, MOMZ, MOMX, MOMY, RHOT, PROG, DENS0, MOMZ0, MOMX0, MOMY0, RHOT0, PROG0, BND_W, BND_E, BND_S, BND_N)
subroutine, public	atmos_dyn_divergence (DDIV, MOMZ, MOMX, MOMY, GSQRT, J13G, J23G, J33G, MAPF, RCDZ, RCDX, RCDY, RFDZ, FDZ)
subroutine	calc_numdiff (work, iwork, data, nd_order, KO, IO, JO, KEE)
subroutine	calc_diff3 (diff, phi, KO, IO, JO)
subroutine, public	atmos_dyn_fct (qflx_anti, phi_in, DENS0, DENS, qflx_hi, qflx_lo, mflx_hi, rdz, rdx, rdy, GSQRT, MAPF, dt, flag_vect)
	Flux Correction Transport Limiter. More...

Detailed Description

module Atmosphere / Dynamics common

Description

common subroutines for Atmospheric dynamical process

Author

Team SCALE

History

• 2013-06-18 (S.Nishizawa) [new] splited from dynamical core

Function/Subroutine Documentation

atmos_dyn_filter_setup()

subroutine, public scale_atmos_dyn_common::atmos_dyn_filter_setup	(	real(rp), dimension(ka,ia,ja,5,3), intent(inout)	num_diff,
		real(rp), dimension(ka,ia,ja,3), intent(inout)	num_diff_q,
		real(rp), dimension(ka), intent(in)	CDZ,
		real(rp), dimension(ia), intent(in)	CDX,
		real(rp), dimension(ja), intent(in)	CDY,
		real(rp), dimension(ka-1), intent(in)	FDZ,
		real(rp), dimension(ia-1), intent(in)	FDX,
		real(rp), dimension(ja-1), intent(in)	FDY
	)

Setup.

Definition at line 96 of file scale_atmos_dyn_common.F90.

References scale_comm::comm_vars8_init(), scale_index::i_dens, scale_index::i_momx, scale_index::i_momy, scale_index::i_momz, scale_index::i_rhot, scale_grid_index::ia, scale_grid_index::ie, scale_grid_index::ihalo, scale_grid_index::is, scale_grid_index::ja, scale_grid_index::je, scale_grid_index::jhalo, scale_grid_index::js, scale_grid_index::ka, scale_grid_index::ke, scale_grid_index::khalo, scale_grid_index::ks, scale_process::prc_mpistop(), scale_grid_index::xdir, scale_grid_index::ydir, and scale_grid_index::zdir.

Referenced by scale_atmos_dyn::atmos_dyn_setup().

    use scale_process, only: &
       prc_mpistop
    use scale_comm, only: &
       comm_vars8_init
    implicit none
    real(RP), intent(inout) :: num_diff(ka,ia,ja,5,3)
    real(RP), intent(inout) :: num_diff_q(ka,ia,ja,3)
    real(RP), intent(in)  :: cdz(ka)
    real(RP), intent(in)  :: cdx(ia)
    real(RP), intent(in)  :: cdy(ja)
    real(RP), intent(in)  :: fdz(ka-1)
    real(RP), intent(in)  :: fdx(ia-1)
    real(RP), intent(in)  :: fdy(ja-1)

    integer :: k, i, j
    !---------------------------------------------------------------------------

    if ( ihalo < 2 .or. jhalo < 2 .or. khalo < 2 ) then
       write(*,*) 'xxx number of HALO must be at least 2 for numrical filter'
       call prc_mpistop
    end if
    
    ! allocation
    allocate( cnz3(3,ka,2) )
    allocate( cnx3(3,ia,2) )
    allocate( cny3(3,ja,2) )
    allocate( cnz4(5,ka,2) )
    allocate( cnx4(5,ia,2) )
    allocate( cny4(5,ja,2) )


    call comm_vars8_init( num_diff(:,:,:,i_dens,zdir), i_comm_dens_z )
    call comm_vars8_init( num_diff(:,:,:,i_dens,xdir), i_comm_dens_x )
    call comm_vars8_init( num_diff(:,:,:,i_dens,ydir), i_comm_dens_y )
    call comm_vars8_init( num_diff(:,:,:,i_momz,zdir), i_comm_momz_z )
    call comm_vars8_init( num_diff(:,:,:,i_momz,xdir), i_comm_momz_x )
    call comm_vars8_init( num_diff(:,:,:,i_momz,ydir), i_comm_momz_y )
    call comm_vars8_init( num_diff(:,:,:,i_momx,zdir), i_comm_momx_z )
    call comm_vars8_init( num_diff(:,:,:,i_momx,xdir), i_comm_momx_x )
    call comm_vars8_init( num_diff(:,:,:,i_momx,ydir), i_comm_momx_y )
    call comm_vars8_init( num_diff(:,:,:,i_momy,zdir), i_comm_momy_z )
    call comm_vars8_init( num_diff(:,:,:,i_momy,xdir), i_comm_momy_x )
    call comm_vars8_init( num_diff(:,:,:,i_momy,ydir), i_comm_momy_y )
    call comm_vars8_init( num_diff(:,:,:,i_rhot,zdir), i_comm_rhot_z )
    call comm_vars8_init( num_diff(:,:,:,i_rhot,xdir), i_comm_rhot_x )
    call comm_vars8_init( num_diff(:,:,:,i_rhot,ydir), i_comm_rhot_y )

    call comm_vars8_init( num_diff_q(:,:,:,zdir), i_comm_qtrc_z )
    call comm_vars8_init( num_diff_q(:,:,:,xdir), i_comm_qtrc_x )
    call comm_vars8_init( num_diff_q(:,:,:,ydir), i_comm_qtrc_y )

#ifdef DEBUG
    cnz3(:,:,:) = undef
    cnx3(:,:,:) = undef
    cny3(:,:,:) = undef
    cnz4(:,:,:) = undef
    cnx4(:,:,:) = undef
    cny4(:,:,:) = undef
#endif

    ! z direction
    do k = ks+1, ke-1
       cnz3(1,k,1) = 1.0_rp / ( fdz(k  ) * cdz(k  ) * fdz(k-1) )
       cnz3(2,k,1) = 1.0_rp / ( fdz(k  ) * cdz(k  ) * fdz(k-1) ) &
                   + 1.0_rp / ( fdz(k-1) * cdz(k  ) * fdz(k-1) ) &
                   + 1.0_rp / ( fdz(k-1) * cdz(k-1) * fdz(k-1) )
    enddo
    do k = ks+2, ke
       cnz3(3,k,1) = 1.0_rp / ( fdz(k-1) * cdz(k  ) * fdz(k-1) ) &
                   + 1.0_rp / ( fdz(k-1) * cdz(k-1) * fdz(k-1) ) &
                   + 1.0_rp / ( fdz(k-1) * cdz(k-1) * fdz(k-2) )
    enddo
    cnz3(1,ks-1,1) = 1.0_rp / ( fdz(ks  ) * cdz(ks+1) * fdz(ks  ) )
    cnz3(1,ks  ,1) = 1.0_rp / ( fdz(ks  ) * cdz(ks  ) * fdz(ks  ) )
    cnz3(2,ks  ,1) = 1.0_rp / ( fdz(ks  ) * cdz(ks  ) * fdz(ks  ) ) &
                   + 1.0_rp / ( fdz(ks  ) * cdz(ks  ) * fdz(ks  ) ) &
                   + 1.0_rp / ( fdz(ks  ) * cdz(ks+1) * fdz(ks  ) )
    cnz3(3,ks  ,1) = 1.0_rp / ( fdz(ks  ) * cdz(ks  ) * fdz(ks  ) ) &
                   + 1.0_rp / ( fdz(ks  ) * cdz(ks+1) * fdz(ks  ) ) &
                   + 1.0_rp / ( fdz(ks  ) * cdz(ks+1) * fdz(ks+1) )
    cnz3(3,ks+1,1) = 1.0_rp / ( fdz(ks  ) * cdz(ks+1) * fdz(ks  ) ) &
                   + 1.0_rp / ( fdz(ks  ) * cdz(ks  ) * fdz(ks  ) ) &
                   + 1.0_rp / ( fdz(ks  ) * cdz(ks  ) * fdz(ks  ) )
    cnz3(1,ke  ,1) = 1.0_rp / ( fdz(ke-1) * cdz(ke  ) * fdz(ke-1) )
    cnz3(2,ke  ,1) = 1.0_rp / ( fdz(ke-1) * cdz(ke  ) * fdz(ke-1) ) &
                   + 1.0_rp / ( fdz(ke-1) * cdz(ke  ) * fdz(ke-1) ) &
                   + 1.0_rp / ( fdz(ke-1) * cdz(ke-1) * fdz(ke-1) )
    cnz3(1,ke+1,1) = 1.0_rp / ( fdz(ke-2) * cdz(ke-1) * fdz(ke-1) )
    cnz3(2,ke+1,1) = 1.0_rp / ( fdz(ke-2) * cdz(ke-1) * fdz(ke-1) ) &
                   + 1.0_rp / ( fdz(ke-1) * cdz(ke-1) * fdz(ke-1) ) &
                   + 1.0_rp / ( fdz(ke-1) * cdz(ke  ) * fdz(ke-1) )
    cnz3(3,ke+1,1) = 1.0_rp / ( fdz(ke-1) * cdz(ke+1) * fdz(ke-1) ) &
                   + 1.0_rp / ( fdz(ke-1) * cdz(ke  ) * fdz(ke-1) ) &
                   + 1.0_rp / ( fdz(ke-1) * cdz(ke  ) * fdz(ke-1) )

    do k = ks, ke-1
       cnz4(1,k,1) = ( cnz3(1,k+1,1)               ) / cdz(k)
       cnz4(2,k,1) = ( cnz3(2,k+1,1) + cnz3(1,k,1) ) / cdz(k)
       cnz4(3,k,1) = ( cnz3(3,k+1,1) + cnz3(2,k,1) ) / cdz(k)
       cnz4(4,k,1) = ( cnz3(1,k  ,1) + cnz3(3,k,1) ) / cdz(k)
       cnz4(5,k,1) = ( cnz3(1,k-1,1)               ) / cdz(k)
    enddo

    do k = ks+1, ke-1
       cnz3(1,k,2) = 1.0_rp / ( cdz(k+1) * fdz(k  ) * cdz(k  ) )
       cnz3(2,k,2) = 1.0_rp / ( cdz(k+1) * fdz(k  ) * cdz(k  ) ) &
                   + 1.0_rp / ( cdz(k  ) * fdz(k  ) * cdz(k  ) ) &
                   + 1.0_rp / ( cdz(k  ) * fdz(k-1) * cdz(k  ) )
       cnz3(3,k,2) = 1.0_rp / ( cdz(k  ) * fdz(k  ) * cdz(k  ) ) &
                   + 1.0_rp / ( cdz(k  ) * fdz(k-1) * cdz(k  ) ) &
                   + 1.0_rp / ( cdz(k  ) * fdz(k-1) * cdz(k-1) )
    enddo
    cnz3(1,ks-1,2) = 1.0_rp / ( cdz(ks  ) * fdz(ks  ) * cdz(ks  ) )
    cnz3(1,ks  ,2) = 1.0_rp / ( cdz(ks+1) * fdz(ks  ) * cdz(ks  ) )
    cnz3(2,ks  ,2) = 1.0_rp / ( cdz(ks+1) * fdz(ks  ) * cdz(ks  ) ) &
                   + 1.0_rp / ( cdz(ks  ) * fdz(ks  ) * cdz(ks  ) ) &
                   + 1.0_rp / ( cdz(ks  ) * fdz(ks  ) * cdz(ks  ) )
    cnz3(3,ks  ,2) = 1.0_rp / ( cdz(ks  ) * fdz(ks  ) * cdz(ks  ) ) &
                   + 1.0_rp / ( cdz(ks  ) * fdz(ks  ) * cdz(ks  ) ) &
                   + 1.0_rp / ( cdz(ks  ) * fdz(ks  ) * cdz(ks+1) )
    cnz3(1,ke  ,2) = 1.0_rp / ( cdz(ke-1) * fdz(ke-1) * cdz(ke  ) )
    cnz3(2,ke  ,2) = 1.0_rp / ( cdz(ke-1) * fdz(ke-1) * cdz(ke  ) ) &
                   + 1.0_rp / ( cdz(ke  ) * fdz(ke-1) * cdz(ke  ) ) &
                   + 1.0_rp / ( cdz(ke  ) * fdz(ke-1) * cdz(ke  ) )
    cnz3(3,ke  ,2) = 1.0_rp / ( cdz(ke  ) * fdz(ke-1) * cdz(ke  ) ) &
                   + 1.0_rp / ( cdz(ke  ) * fdz(ke-1) * cdz(ke  ) ) &
                   + 1.0_rp / ( cdz(ke  ) * fdz(ke-1) * cdz(ke-1) )
    cnz3(1,ke+1,2) = 1.0_rp / ( cdz(ke-2) * fdz(ke-2) * cdz(ke-1) )
    cnz3(2,ke+1,2) = 1.0_rp / ( cdz(ke-2) * fdz(ke-2) * cdz(ke-1) ) &
                   + 1.0_rp / ( cdz(ke-1) * fdz(ke-2) * cdz(ke-1) ) &
                   + 1.0_rp / ( cdz(ke-1) * fdz(ke-1) * cdz(ke-1) )
    cnz3(3,ke+1,2) = 1.0_rp / ( cdz(ke-1) * fdz(ke-2) * cdz(ke-1) ) &
                   + 1.0_rp / ( cdz(ke-1) * fdz(ke-1) * cdz(ke-1) ) &
                   + 1.0_rp / ( cdz(ke-1) * fdz(ke-1) * cdz(ke  ) )

    do k = ks, ke-1
       cnz4(1,k,2) = ( cnz3(1,k+1,2)               ) / fdz(k)
       cnz4(2,k,2) = ( cnz3(2,k+1,2) + cnz3(1,k,2) ) / fdz(k)
       cnz4(3,k,2) = ( cnz3(3,k+1,2) + cnz3(2,k,2) ) / fdz(k)
       cnz4(4,k,2) = ( cnz3(1,k  ,2) + cnz3(3,k,2) ) / fdz(k)
       cnz4(5,k,2) = ( cnz3(1,k-1,2)               ) / fdz(k)
    enddo
!    CNZ4(1,KE,2) = ( CNZ3(1,KE+1,2)                ) / FDZ(KE-1)
    cnz4(2,ke,2) = ( cnz3(2,ke+1,2) + cnz3(1,ke,2) ) / fdz(ke-1)
    cnz4(3,ke,2) = ( cnz3(3,ke+1,2) + cnz3(2,ke,2) ) / fdz(ke-1)
    cnz4(4,ke,2) = ( cnz3(1,ke  ,2) + cnz3(3,ke,2) ) / fdz(ke-1)

    ! x direction
    cnx3(1,is-1,1) = 1.0_rp / ( fdx(is-1) * cdx(is-1) * fdx(is-2) )
    do i = is, ie+1
       cnx3(1,i,1) = 1.0_rp / ( fdx(i  ) * cdx(i  ) * fdx(i-1) )
       cnx3(2,i,1) = 1.0_rp / ( fdx(i  ) * cdx(i  ) * fdx(i-1) ) &
                   + 1.0_rp / ( fdx(i-1) * cdx(i  ) * fdx(i-1) ) &
                   + 1.0_rp / ( fdx(i-1) * cdx(i-1) * fdx(i-1) )
       cnx3(3,i,1) = 1.0_rp / ( fdx(i-1) * cdx(i  ) * fdx(i-1) ) &
                   + 1.0_rp / ( fdx(i-1) * cdx(i-1) * fdx(i-1) ) &
                   + 1.0_rp / ( fdx(i-1) * cdx(i-1) * fdx(i-2) )
    enddo

    do i = is, ie
       cnx4(1,i,1) = ( cnx3(1,i+1,1)               ) / cdx(i)
       cnx4(2,i,1) = ( cnx3(2,i+1,1) + cnx3(1,i,1) ) / cdx(i)
       cnx4(3,i,1) = ( cnx3(3,i+1,1) + cnx3(2,i,1) ) / cdx(i)
       cnx4(4,i,1) = ( cnx3(1,i  ,1) + cnx3(3,i,1) ) / cdx(i)
       cnx4(5,i,1) = ( cnx3(1,i-1,1)               ) / cdx(i)
    enddo

    do i = is-1, ie+1
       cnx3(1,i,2) = 1.0_rp / ( cdx(i+1) * fdx(i  ) * cdx(i  ) )
       cnx3(2,i,2) = 1.0_rp / ( cdx(i+1) * fdx(i  ) * cdx(i  ) ) &
                   + 1.0_rp / ( cdx(i  ) * fdx(i  ) * cdx(i  ) ) &
                   + 1.0_rp / ( cdx(i  ) * fdx(i-1) * cdx(i  ) )
       cnx3(3,i,2) = 1.0_rp / ( cdx(i  ) * fdx(i  ) * cdx(i  ) ) &
                   + 1.0_rp / ( cdx(i  ) * fdx(i-1) * cdx(i  ) ) &
                   + 1.0_rp / ( cdx(i  ) * fdx(i-1) * cdx(i-1) )
    enddo

    do i = is, ie
       cnx4(1,i,2) = ( cnx3(1,i+1,2)               ) / fdx(i)
       cnx4(2,i,2) = ( cnx3(2,i+1,2) + cnx3(1,i,2) ) / fdx(i)
       cnx4(3,i,2) = ( cnx3(3,i+1,2) + cnx3(2,i,2) ) / fdx(i)
       cnx4(4,i,2) = ( cnx3(1,i  ,2) + cnx3(3,i,2) ) / fdx(i)
       cnx4(5,i,2) = ( cnx3(1,i-1,2)               ) / fdx(i)
    enddo

    ! y direction
    cny3(1,js-1,1) = 1.0_rp / ( fdy(js-1) * cdy(js-1) * fdy(js-2) )
    do j = js, je+1
       cny3(1,j,1) = 1.0_rp / ( fdy(j  ) * cdy(j  ) * fdy(j-1) )
       cny3(2,j,1) = 1.0_rp / ( fdy(j  ) * cdy(j  ) * fdy(j-1) ) &
                   + 1.0_rp / ( fdy(j-1) * cdy(j  ) * fdy(j-1) ) &
                   + 1.0_rp / ( fdy(j-1) * cdy(j-1) * fdy(j-1) )
       cny3(3,j,1) = 1.0_rp / ( fdy(j-1) * cdy(j  ) * fdy(j-1) ) &
                   + 1.0_rp / ( fdy(j-1) * cdy(j-1) * fdy(j-1) ) &
                   + 1.0_rp / ( fdy(j-1) * cdy(j-1) * fdy(j-2) )
    enddo

    do j = js, je
       cny4(1,j,1) = ( cny3(1,j+1,1)               ) / cdy(j)
       cny4(2,j,1) = ( cny3(2,j+1,1) + cny3(1,j,1) ) / cdy(j)
       cny4(3,j,1) = ( cny3(3,j+1,1) + cny3(2,j,1) ) / cdy(j)
       cny4(4,j,1) = ( cny3(1,j  ,1) + cny3(3,j,1) ) / cdy(j)
       cny4(5,j,1) = ( cny3(1,j-1,1)               ) / cdy(j)
    enddo

    do j = js-1, je+1
       cny3(1,j,2) = 1.0_rp / ( cdy(j+1) * fdy(j  ) * cdy(j  ) )
       cny3(2,j,2) = 1.0_rp / ( cdy(j+1) * fdy(j  ) * cdy(j  ) ) &
                   + 1.0_rp / ( cdy(j  ) * fdy(j  ) * cdy(j  ) ) &
                   + 1.0_rp / ( cdy(j  ) * fdy(j-1) * cdy(j  ) )
       cny3(3,j,2) = 1.0_rp / ( cdy(j  ) * fdy(j  ) * cdy(j  ) ) &
                   + 1.0_rp / ( cdy(j  ) * fdy(j-1) * cdy(j  ) ) &
                   + 1.0_rp / ( cdy(j  ) * fdy(j-1) * cdy(j-1) )
    enddo

    do j = js, je
       cny4(1,j,2) = ( cny3(1,j+1,2)               ) / fdy(j)
       cny4(2,j,2) = ( cny3(2,j+1,2) + cny3(1,j,2) ) / fdy(j)
       cny4(3,j,2) = ( cny3(3,j+1,2) + cny3(2,j,2) ) / fdy(j)
       cny4(4,j,2) = ( cny3(1,j  ,2) + cny3(3,j,2) ) / fdy(j)
       cny4(5,j,2) = ( cny3(1,j-1,2)               ) / fdy(j)
    enddo

    return

Here is the call graph for this function:

Here is the caller graph for this function:

atmos_dyn_numfilter_coef()

subroutine, public scale_atmos_dyn_common::atmos_dyn_numfilter_coef	(	real(rp), dimension(ka,ia,ja,5,3), intent(out)	num_diff,
		real(rp), dimension(ka,ia,ja), intent(in)	DENS,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMZ,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMX,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMY,
		real(rp), dimension(ka,ia,ja), intent(in)	RHOT,
		real(rp), dimension(ka), intent(in)	CDZ,
		real(rp), dimension(ia), intent(in)	CDX,
		real(rp), dimension(ja), intent(in)	CDY,
		real(rp), dimension(ka-1), intent(in)	FDZ,
		real(rp), dimension(ia-1), intent(in)	FDX,
		real(rp), dimension(ja-1), intent(in)	FDY,
		real(rp), intent(in)	DT,
		real(rp), dimension(ka,ia,ja), intent(in)	REF_dens,
		real(rp), dimension(ka,ia,ja), intent(in)	REF_pott,
		real(rp), intent(in)	ND_COEF,
		integer, intent(in)	ND_ORDER,
		real(rp), intent(in)	ND_SFC_FACT,
		logical, intent(in)	ND_USE_RS
	)

Calc coefficient of numerical filter.

Definition at line 330 of file scale_atmos_dyn_common.F90.

References calc_numdiff(), scale_index::i_dens, scale_index::i_momx, scale_index::i_momy, scale_index::i_momz, scale_index::i_rhot, scale_grid_index::ie, scale_grid_index::is, scale_grid_index::je, scale_grid_index::js, scale_grid_index::ka, scale_grid_index::ke, scale_grid_index::ks, scale_prof::prof_rapend(), scale_prof::prof_rapstart(), scale_grid_index::xdir, scale_grid_index::ydir, and scale_grid_index::zdir.

Referenced by scale_atmos_dyn_tinteg_large_euler::atmos_dyn_tinteg_large_euler(), scale_atmos_dyn_tinteg_large_rk3::atmos_dyn_tinteg_large_rk3(), and scale_atmos_dyn_tstep_large_fvm_heve::atmos_dyn_tstep_large_fvm_heve().

    use scale_comm, only: &
       comm_vars8, &
       comm_wait
    implicit none

    real(RP), intent(out) :: num_diff(ka,ia,ja,5,3)

    real(RP), intent(in)  :: dens(ka,ia,ja)
    real(RP), intent(in)  :: momz(ka,ia,ja)
    real(RP), intent(in)  :: momx(ka,ia,ja)
    real(RP), intent(in)  :: momy(ka,ia,ja)
    real(RP), intent(in)  :: rhot(ka,ia,ja)

    real(RP), intent(in)  :: cdz(ka)
    real(RP), intent(in)  :: cdx(ia)
    real(RP), intent(in)  :: cdy(ja)
    real(RP), intent(in)  :: fdz(ka-1)
    real(RP), intent(in)  :: fdx(ia-1)
    real(RP), intent(in)  :: fdy(ja-1)

    real(RP), intent(in)  :: dt

    real(RP), intent(in)  :: ref_dens(ka,ia,ja)
    real(RP), intent(in)  :: ref_pott(ka,ia,ja)

    real(RP), intent(in)  :: nd_coef
    integer,  intent(in)  :: nd_order
    real(RP), intent(in)  :: nd_sfc_fact
    logical,  intent(in)  :: nd_use_rs

    ! diagnostic variables
    real(RP) :: velz (ka,ia,ja) ! velocity w [m/s]
    real(RP) :: velx (ka,ia,ja) ! velocity u [m/s]
    real(RP) :: vely (ka,ia,ja) ! velocity v [m/s]
    real(RP) :: pott (ka,ia,ja) ! potential temperature [K]

    real(RP) :: dens_diff(ka,ia,ja)     ! anomary of density
    real(RP) :: pott_diff(ka,ia,ja)     ! anomary of rho * pott

    real(RP) :: work(ka,ia,ja,3,2)
    integer  :: iwork

    real(RP) :: diff4
    integer  :: nd_order4
    real(RP) :: nd_coef_cdz(ka)
    real(RP) :: nd_coef_cdx(ia)
    real(RP) :: nd_coef_cdy(ja)
    real(RP) :: nd_coef_fdz(ka-1)
    real(RP) :: nd_coef_fdx(ia-1)
    real(RP) :: nd_coef_fdy(ja-1)

    integer :: k, i, j
    !---------------------------------------------------------------------------

    ! numerical diffusion
    nd_order4 = nd_order * 4
    diff4 = nd_coef / ( 2**(nd_order4) * dt )
    do k = ks-1, ke
       nd_coef_cdz(k) = diff4 * cdz(k)**nd_order4
    end do
    do k = ks+1, ke-1
       nd_coef_fdz(k) = diff4 * fdz(k)**nd_order4
    end do
    do i = is, ie
       nd_coef_cdx(i) = diff4 * cdx(i)**nd_order4
       nd_coef_fdx(i) = diff4 * fdx(i)**nd_order4
    end do
    do j = js, je
       nd_coef_cdy(j) = diff4 * cdy(j)**nd_order4
       nd_coef_fdy(j) = diff4 * fdy(j)**nd_order4
    end do


    !###########################################################################
    ! 1st order coefficients
    !###########################################################################

    if ( .NOT. nd_use_rs ) then

       call prof_rapstart("NumFilter_Main", 3)

       do j = js-2, je+2
       do i = is-2, ie+2
       do k = ks, ke
          pott(k,i,j) = rhot(k,i,j) / dens(k,i,j)
       end do
       end do
       end do

       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
       do k = ks+1, ke-1
          dens_diff(k,i,j) = ( ( dens(k,i,j)                                             ) * 3.0_rp &
                             + ( dens(k,i+1,j)+dens(k,i-1,j)+dens(k,i,j+1)+dens(k,i,j-1) ) * 2.0_rp &
                             + ( dens(k,i+2,j)+dens(k,i-2,j)+dens(k,i,j+2)+dens(k,i,j-2) ) &
                             + ( dens(k+1,i,j)+dens(k-1,i,j)                             ) * 2.0_rp &
                             ) / 19.0_rp

          pott_diff(k,i,j) = ( ( pott(k,i,j)                                             ) * 3.0_rp &
                             + ( pott(k,i+1,j)+pott(k,i-1,j)+pott(k,i,j+1)+pott(k,i,j-1) ) * 2.0_rp &
                             + ( pott(k,i+2,j)+pott(k,i-2,j)+pott(k,i,j+2)+pott(k,i,j-2) ) &
                             + ( pott(k+1,i,j)+pott(k-1,i,j)                             ) * 2.0_rp &
                             ) / 19.0_rp
       enddo
       enddo
       enddo

       do j  = js, je
       do i  = is, ie
          dens_diff(ks,i,j) = ( ( dens(ks,i,j)                                                ) * 3.0_rp &
                              + ( dens(ks,i+1,j)+dens(ks,i-1,j)+dens(ks,i,j+1)+dens(ks,i,j-1) ) * 2.0_rp &
                              + ( dens(ks,i+2,j)+dens(ks,i-2,j)+dens(ks,i,j+2)+dens(ks,i,j-2) ) &
                              + ( dens(ks+1,i,j)                                              ) * 2.0_rp &
                              ) / 17.0_rp
          dens_diff(ke,i,j) = ( ( dens(ke,i,j)                                                ) * 3.0_rp &
                              + ( dens(ke,i+1,j)+dens(ke,i-1,j)+dens(ke,i,j+1)+dens(ke,i,j-1) ) * 2.0_rp &
                              + ( dens(ke,i+2,j)+dens(ke,i-2,j)+dens(ke,i,j+2)+dens(ke,i,j-2) ) &
                              + ( dens(ke-1,i,j)                                              ) * 2.0_rp &
                              ) / 17.0_rp

          pott_diff(ks,i,j) = ( ( pott(ks,i,j)                                                ) * 3.0_rp &
                              + ( pott(ks,i+1,j)+pott(ks,i-1,j)+pott(ks,i,j+1)+pott(ks,i,j-1) ) * 2.0_rp &
                              + ( pott(ks,i+2,j)+pott(ks,i-2,j)+pott(ks,i,j+2)+pott(ks,i,j-2) ) &
                              + ( pott(ks+1,i,j)                                              ) * 2.0_rp &
                              ) / 17.0_rp
          pott_diff(ke,i,j) = ( ( pott(ke,i,j)                                                ) * 3.0_rp &
                              + ( pott(ke,i+1,j)+pott(ke,i-1,j)+pott(ke,i,j+1)+pott(ke,i,j-1) ) * 2.0_rp &
                              + ( pott(ke,i+2,j)+pott(ke,i-2,j)+pott(ke,i,j+2)+pott(ke,i,j-2) ) &
                              + ( pott(ke-1,i,j)                                              ) * 2.0_rp &
                              ) / 17.0_rp
       end do
       end do

       call prof_rapend  ("NumFilter_Main", 3)

       call prof_rapstart("NumFilter_Comm", 3)

       call comm_vars8( dens_diff,  1 )
       call comm_vars8( pott_diff,  2 )

       call comm_wait ( dens_diff,  1 )
       call comm_wait ( pott_diff,  2 )

       call prof_rapend  ("NumFilter_Comm", 3)

    end if


    !-----< density >-----

    if ( nd_use_rs ) then

       call prof_rapstart("NumFilter_Main", 3)

       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js-1, je+2
       do i = is-1, ie+2
       do k = ks, ke
          dens_diff(k,i,j) = dens(k,i,j) - ref_dens(k,i,j)
       enddo
       enddo
       enddo

       call prof_rapend("NumFilter_Main", 3)

    endif

    call calc_numdiff( work, iwork, & ! (out)
                       dens_diff, & ! (in)
                       nd_order, & ! (in)
                       0, 0, 0, ke )

    call prof_rapstart("NumFilter_Main", 3)

    !-----< density >-----

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js, je
    do i = is, ie
    do k = ks-1, ke
       num_diff(k,i,j,i_dens,zdir) = work(k,i,j,zdir,iwork) * nd_coef_cdz(k)
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-2,i,j,i_dens,zdir) = 0.0_rp
       num_diff(ke+1:ka  ,i,j,i_dens,zdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff(k,i,j,i_dens,xdir) = work(k,i,j,xdir,iwork) * nd_coef_cdx(i)
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-1,i,j,i_dens,xdir) = 0.0_rp
       num_diff(ks  ,i,j,i_dens,xdir) = num_diff(ks  ,i,j,i_dens,xdir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_dens,xdir) = num_diff(ks+1,i,j,i_dens,xdir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff(ke+1:ka  ,i,j,i_dens,xdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff(k,i,j,i_dens,ydir) = work(k,i,j,ydir,iwork) * nd_coef_cdy(j)
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-1,i,j,i_dens,ydir) = 0.0_rp
       num_diff(ks  ,i,j,i_dens,ydir) = num_diff(ks  ,i,j,i_dens,ydir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_dens,ydir) = num_diff(ks+1,i,j,i_dens,ydir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff(ke+1:ka  ,i,j,i_dens,ydir) = 0.0_rp
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call prof_rapstart("NumFilter_Comm", 3)

    call comm_vars8( num_diff(:,:,:,i_dens,zdir),  i_comm_dens_z )
    call comm_vars8( num_diff(:,:,:,i_dens,xdir),  i_comm_dens_x )
    call comm_vars8( num_diff(:,:,:,i_dens,ydir),  i_comm_dens_y )

    call prof_rapend  ("NumFilter_Comm", 3)


    !-----< z-momentum >-----

    call prof_rapstart("NumFilter_Main", 3)

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js-2, je+2
    do i = is-2, ie+2
    do k = ks, ke-1
       velz(k,i,j) = 2.0_rp * momz(k,i,j) / ( dens(k+1,i,j)+dens(k,i,j) )
    enddo
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call calc_numdiff( work, iwork, & ! (out)
                       velz, & ! (in)
                       nd_order, & ! (in)
                       1, 0, 0, ke-1 )

    call prof_rapstart("NumFilter_Main", 3)

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js, je
    do i = is, ie
    do k = ks+1, ke-1
       num_diff(k,i,j,i_momz,zdir) = work(k,i,j,zdir,iwork) * nd_coef_fdz(k) &
                                   * dens(k,i,j)
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff( 1:ks,i,j,i_momz,zdir) = 0.0_rp
       num_diff(ke:ka,i,j,i_momz,zdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke-1
       num_diff(k,i,j,i_momz,xdir) = work(k,i,j,xdir,iwork) * nd_coef_cdx(i) &
                                   * 0.25_rp * ( dens(k+1,i+1,j)+dens(k+1,i,j)+dens(k,i+1,j)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff( 1:ks-1,i,j,i_momz,xdir) = 0.0_rp
       num_diff(ks  ,i,j,i_momz,xdir) = num_diff(ks  ,i,j,i_momz,xdir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_momz,xdir) = num_diff(ks+1,i,j,i_momz,xdir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff(ke:ka  ,i,j,i_momz,xdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke-1
       num_diff(k,i,j,i_momz,ydir) = work(k,i,j,ydir,iwork) * nd_coef_cdy(j) &
                                   * 0.25_rp * ( dens(k+1,i,j+1)+dens(k+1,i,j)+dens(k,i,j+1)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff( 1:ks-1,i,j,i_momz,ydir) = 0.0_rp
       num_diff(ks  ,i,j,i_momz,ydir) = num_diff(ks  ,i,j,i_momz,ydir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_momz,ydir) = num_diff(ks+1,i,j,i_momz,ydir) * (1.0_rp + nd_sfc_fact) * 0.5_rp

       num_diff(ke:ka  ,i,j,i_momz,ydir) = 0.0_rp
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call prof_rapstart("NumFilter_Comm", 3)

    call comm_vars8( num_diff(:,:,:,i_momz,zdir), i_comm_momz_z )
    call comm_vars8( num_diff(:,:,:,i_momz,xdir), i_comm_momz_x )
    call comm_vars8( num_diff(:,:,:,i_momz,ydir), i_comm_momz_y )

    call prof_rapend  ("NumFilter_Comm", 3)


    !-----< x-momentum >-----

    call prof_rapstart("NumFilter_Main", 3)

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js-2, je+2
    do i = is-2, ie+1
    do k = ks, ke
       velx(k,i,j) = 2.0_rp * momx(k,i,j) / ( dens(k,i+1,j)+dens(k,i,j) )
    enddo
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call calc_numdiff( work, iwork, & ! (out)
                       velx, & ! (in)
                       nd_order, & ! (in)
                       0, 1, 0, ke )


    call prof_rapstart("NumFilter_Main", 3)

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js, je
    do i = is, ie
    do k = ks, ke-1
       num_diff(k,i,j,i_momx,zdir) = work(k,i,j,zdir,iwork) * nd_coef_cdz(k) &
                                   * 0.25_rp * ( dens(k+1,i+1,j)+dens(k+1,i,j)+dens(k,i+1,j)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff( 1:ks-1,i,j,i_momx,zdir) = 0.0_rp
       num_diff(ke:ka  ,i,j,i_momx,zdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff(k,i,j,i_momx,xdir) = work(k,i,j,xdir,iwork) * nd_coef_fdx(i) &
                                   * dens(k,i,j)
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-1,i,j,i_momx,xdir) = 0.0_rp
       num_diff(ks  ,i,j,i_momx,xdir) = num_diff(ks  ,i,j,i_momx,xdir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_momx,xdir) = num_diff(ks+1,i,j,i_momx,xdir) * (1.0_rp + nd_sfc_fact) * 0.5_rp

       num_diff(ke+1:ka  ,i,j,i_momx,xdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff(k,i,j,i_momx,ydir) = work(k,i,j,ydir,iwork) * nd_coef_cdy(j) &
                                   * 0.25_rp * ( dens(k,i+1,j+1)+dens(k,i+1,j)+dens(k,i,j+1)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-1,i,j,i_momx,ydir) = 0.0_rp
       num_diff(ks  ,i,j,i_momx,ydir) = num_diff(ks  ,i,j,i_momx,ydir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_momx,ydir) = num_diff(ks+1,i,j,i_momx,ydir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff(ke+1:ka  ,i,j,i_momx,ydir) = 0.0_rp
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call prof_rapstart("NumFilter_Comm", 3)

    call comm_vars8( num_diff(:,:,:,i_momx,zdir), i_comm_momx_z )
    call comm_vars8( num_diff(:,:,:,i_momx,xdir), i_comm_momx_x )
    call comm_vars8( num_diff(:,:,:,i_momx,ydir), i_comm_momx_y )

    call prof_rapend  ("NumFilter_Comm", 3)


    !-----< y-momentum >-----

    call prof_rapstart("NumFilter_Main", 3)

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js-2, je+1
    do i = is-2, ie+2
    do k = ks, ke
       vely(k,i,j) = 2.0_rp * momy(k,i,j) / ( dens(k,i,j+1)+dens(k,i,j) )
    enddo
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call calc_numdiff( work, iwork, & ! (out)
                       vely, & ! (in)
                       nd_order, & ! (in)
                       0, 0, 1, ke )

    call prof_rapstart("NumFilter_Main", 3)

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js, je
    do i = is, ie
    do k = ks, ke-1
       num_diff(k,i,j,i_momy,zdir) = work(k,i,j,zdir,iwork) * nd_coef_cdz(k) &
                                   * 0.25_rp * ( dens(k+1,i,j+1)+dens(k+1,i,j)+dens(k,i,j+1)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff( 1:ks-1,i,j,i_momy,zdir) = 0.0_rp
       num_diff(ke:ka  ,i,j,i_momy,zdir) = 0.0_rp
    end do
    end do

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff(k,i,j,i_momy,xdir) = work(k,i,j,xdir,iwork) * nd_coef_cdx(i) &
                                   * 0.25_rp * ( dens(k,i+1,j+1)+dens(k,i,j+1)+dens(k,i+1,j)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-1,i,j,i_momy,xdir) = 0.0_rp
       num_diff(ks  ,i,j,i_momy,xdir) = num_diff(ks  ,i,j,i_momy,xdir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_momy,xdir) = num_diff(ks+1,i,j,i_momy,xdir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff(ke+1:ka  ,i,j,i_momy,xdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff(k,i,j,i_momy,ydir) = work(k,i,j,ydir,iwork) * nd_coef_fdy(j) &
                                   * dens(k,i,j)
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-1,i,j,i_momy,ydir) = 0.0_rp
       num_diff(ks  ,i,j,i_momy,ydir) = num_diff(ks  ,i,j,i_momy,ydir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_momy,ydir) = num_diff(ks+1,i,j,i_momy,ydir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff(ke+1:ka  ,i,j,i_momy,ydir) = 0.0_rp
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call prof_rapstart("NumFilter_Comm", 3)

    call comm_vars8( num_diff(:,:,:,i_momy,zdir), i_comm_momy_z )
    call comm_vars8( num_diff(:,:,:,i_momy,xdir), i_comm_momy_x )
    call comm_vars8( num_diff(:,:,:,i_momy,ydir), i_comm_momy_y )

    call prof_rapend  ("NumFilter_Comm", 3)

    !-----< rho * theta >-----

    call prof_rapstart("NumFilter_Main", 3)

    if ( nd_use_rs ) then
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js-1, je+2
       do i = is-1, ie+2
       do k = ks, ke
          pott_diff(k,i,j) = rhot(k,i,j) / dens(k,i,j) - ref_pott(k,i,j)
       enddo
       enddo
       enddo
    endif

    call prof_rapend  ("NumFilter_Main", 3)

    call calc_numdiff( work, iwork, & ! (out)
                       pott_diff, & ! (in)
                       nd_order, & ! (in)
                       0, 0, 0, ke )

    call prof_rapstart("NumFilter_Main", 3)

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js, je
    do i = is, ie
    do k = ks, ke-1
       num_diff(k,i,j,i_rhot,zdir) = work(k,i,j,zdir,iwork) * nd_coef_cdz(k) &
                                   * 0.5_rp * ( dens(k+1,i,j)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-2,i,j,i_rhot,zdir) = 0.0_rp
       num_diff(ks-1,i,j,i_rhot,zdir) = work(ks-1,i,j,zdir,iwork) * nd_coef_cdz(ks-1) &
                                      * dens(ks,i,j)
       num_diff(ke  ,i,j,i_rhot,zdir) = work(ke  ,i,j,zdir,iwork) * nd_coef_cdz(ke  ) &
                                      * dens(ke,i,j)
       num_diff(ke+1:ka  ,i,j,i_rhot,zdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff(k,i,j,i_rhot,xdir) = work(k,i,j,xdir,iwork) * nd_coef_cdx(i) &
                                   * 0.5_rp * ( dens(k,i+1,j)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-1,i,j,i_rhot,xdir) = 0.0_rp
       num_diff(ks  ,i,j,i_rhot,xdir) = num_diff(ks  ,i,j,i_rhot,xdir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_rhot,xdir) = num_diff(ks+1,i,j,i_rhot,xdir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff(ke+1:ka  ,i,j,i_rhot,xdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff(k,i,j,i_rhot,ydir) = work(k,i,j,ydir,iwork) * nd_coef_cdy(j) &
                                   * 0.5_rp * ( dens(k,i,j+1)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff(   1:ks-1,i,j,i_rhot,ydir) = 0.0_rp
       num_diff(ks  ,i,j,i_rhot,ydir) = num_diff(ks  ,i,j,i_rhot,ydir) * nd_sfc_fact
       num_diff(ks+1,i,j,i_rhot,ydir) = num_diff(ks+1,i,j,i_rhot,ydir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff(ke+1:ka  ,i,j,i_rhot,ydir) = 0.0_rp
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call prof_rapstart("NumFilter_Comm", 3)

    call comm_vars8( num_diff(:,:,:,i_rhot,zdir), i_comm_rhot_z )
    call comm_vars8( num_diff(:,:,:,i_rhot,xdir), i_comm_rhot_x )
    call comm_vars8( num_diff(:,:,:,i_rhot,ydir), i_comm_rhot_y )

    call comm_wait ( num_diff(:,:,:,i_dens,zdir), i_comm_dens_z )
    call comm_wait ( num_diff(:,:,:,i_dens,xdir), i_comm_dens_x )
    call comm_wait ( num_diff(:,:,:,i_dens,ydir), i_comm_dens_y )
    call comm_wait ( num_diff(:,:,:,i_momz,zdir), i_comm_momz_z )
    call comm_wait ( num_diff(:,:,:,i_momz,xdir), i_comm_momz_x )
    call comm_wait ( num_diff(:,:,:,i_momz,ydir), i_comm_momz_y )
    call comm_wait ( num_diff(:,:,:,i_momx,zdir), i_comm_momx_z )
    call comm_wait ( num_diff(:,:,:,i_momx,xdir), i_comm_momx_x )
    call comm_wait ( num_diff(:,:,:,i_momx,ydir), i_comm_momx_y )
    call comm_wait ( num_diff(:,:,:,i_momy,zdir), i_comm_momy_z )
    call comm_wait ( num_diff(:,:,:,i_momy,xdir), i_comm_momy_x )
    call comm_wait ( num_diff(:,:,:,i_momy,ydir), i_comm_momy_y )
    call comm_wait ( num_diff(:,:,:,i_rhot,zdir), i_comm_rhot_z )
    call comm_wait ( num_diff(:,:,:,i_rhot,xdir), i_comm_rhot_x )
    call comm_wait ( num_diff(:,:,:,i_rhot,ydir), i_comm_rhot_y )

    call prof_rapend  ("NumFilter_Comm", 3)

    return

Here is the call graph for this function:

Here is the caller graph for this function:

atmos_dyn_numfilter_coef_q()

subroutine, public scale_atmos_dyn_common::atmos_dyn_numfilter_coef_q	(	real(rp), dimension(ka,ia,ja,3), intent(out)	num_diff_q,
		real(rp), dimension(ka,ia,ja), intent(in)	DENS,
		real(rp), dimension(ka,ia,ja), intent(in)	QTRC,
		real(rp), dimension(ka), intent(in)	CDZ,
		real(rp), dimension(ia), intent(in)	CDX,
		real(rp), dimension(ja), intent(in)	CDY,
		real(rp), intent(in)	dt,
		real(rp), dimension(ka,ia,ja), intent(in)	REF_qv,
		integer, intent(in)	iq,
		real(rp), intent(in)	ND_COEF,
		integer, intent(in)	ND_ORDER,
		real(rp), intent(in)	ND_SFC_FACT,
		logical, intent(in)	ND_USE_RS
	)

Calc coefficient of numerical filter.

Definition at line 931 of file scale_atmos_dyn_common.F90.

References calc_numdiff(), scale_tracer::i_qv, scale_grid_index::ie, scale_grid_index::is, scale_grid_index::je, scale_grid_index::js, scale_grid_index::ka, scale_grid_index::ke, scale_grid_index::ks, scale_prof::prof_rapend(), scale_prof::prof_rapstart(), scale_grid_index::xdir, scale_grid_index::ydir, and scale_grid_index::zdir.

Referenced by scale_atmos_dyn_tinteg_large_euler::atmos_dyn_tinteg_large_euler(), scale_atmos_dyn_tinteg_large_rk3::atmos_dyn_tinteg_large_rk3(), and scale_atmos_dyn_tstep_large_fvm_heve::atmos_dyn_tstep_large_fvm_heve().

    use scale_comm, only: &
       comm_vars8, &
       comm_wait
    implicit none

    real(RP), intent(out) :: num_diff_q(ka,ia,ja,3)

    real(RP), intent(in)  :: dens(ka,ia,ja)
    real(RP), intent(in)  :: qtrc(ka,ia,ja)

    real(RP), intent(in)  :: cdz(ka)
    real(RP), intent(in)  :: cdx(ia)
    real(RP), intent(in)  :: cdy(ja)

    real(RP), intent(in)  :: dt

    real(RP), intent(in)  :: ref_qv(ka,ia,ja)
    integer,  intent(in)  :: iq

    real(RP), intent(in)  :: nd_coef
    integer,  intent(in)  :: nd_order
    real(RP), intent(in)  :: nd_sfc_fact
    logical,  intent(in)  :: nd_use_rs

    real(RP) :: qv_diff(ka,ia,ja) ! anomary of water vapor

    real(RP) :: work(ka,ia,ja,3,2)
    integer  :: iwork

    real(RP) :: diff4
    integer  :: nd_order4
    real(RP) :: nd_coef_cdz(ka)
    real(RP) :: nd_coef_cdx(ia)
    real(RP) :: nd_coef_cdy(ja)

    integer :: k, i, j
    !---------------------------------------------------------------------------

    !###########################################################################
    ! 1st order coefficients
    !###########################################################################

    nd_order4 = nd_order * 4
    diff4 = nd_coef / ( 2**(nd_order4) * dt )
    do k = ks-1, ke
       nd_coef_cdz(k) = diff4 * cdz(k)**nd_order4
    end do
    do i = is, ie
       nd_coef_cdx(i) = diff4 * cdx(i)**nd_order4
    end do
    do j = js, je
       nd_coef_cdy(j) = diff4 * cdy(j)**nd_order4
    end do

    if ( iq == i_qv .AND. (.NOT. nd_use_rs) ) then

       call prof_rapstart("NumFilter_Main", 3)

       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js-1, je+2
       do i = is-1, ie+2
       do k = ks+1, ke-1
          qv_diff(k,i,j) = ( ( qtrc(k,i,j)                                             ) * 3.0_rp &
                           + ( qtrc(k,i+1,j)+qtrc(k,i-1,j)+qtrc(k,i,j+1)+qtrc(k,i,j-1) ) * 2.0_rp &
                           + ( qtrc(k,i+2,j)+qtrc(k,i-2,j)+qtrc(k,i,j+2)+qtrc(k,i,j-2) ) &
                           + ( qtrc(k+1,i,j)+qtrc(k-1,i,j)                             ) * 2.0_rp &
                           ) / 19.0_rp
       enddo
       enddo
       enddo

       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j  = js-1, je+2
       do i  = is-1, ie+2
          qv_diff(ks,i,j) = ( ( qtrc(ks,i,j)                                                ) * 3.0_rp &
                            + ( qtrc(ks,i+1,j)+qtrc(ks,i-1,j)+qtrc(ks,i,j+1)+qtrc(ks,i,j-1) ) * 2.0_rp &
                            + ( qtrc(ks,i+2,j)+qtrc(ks,i-2,j)+qtrc(ks,i,j+2)+qtrc(ks,i,j-2) ) &
                            + ( qtrc(ks+1,i,j)                                              ) * 2.0_rp &
                            ) / 17.0_rp
          qv_diff(ke,i,j) = ( ( qtrc(ke,i,j)                                                ) * 3.0_rp &
                            + ( qtrc(ke,i+1,j)+qtrc(ke,i-1,j)+qtrc(ke,i,j+1)+qtrc(ke,i,j-1) ) * 2.0_rp &
                            + ( qtrc(ke,i+2,j)+qtrc(ke,i-2,j)+qtrc(ke,i,j+2)+qtrc(ke,i,j-2) ) &
                            + ( qtrc(ke-1,i,j)                                              ) * 2.0_rp &
                            ) / 17.0_rp
       end do
       end do

       call prof_rapend  ("NumFilter_Main", 3)

       call prof_rapstart("NumFilter_Comm", 3)

       call comm_vars8(qv_diff, 1)
       call comm_wait (qv_diff, 1)

       call prof_rapend  ("NumFilter_Comm", 3)

    end if

    if ( iq == i_qv ) then

       if ( nd_use_rs ) then

          call prof_rapstart("NumFilter_Main", 3)

          !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
          do j = js-1, je+2
          do i = is-1, ie+2
          do k = ks, ke
             qv_diff(k,i,j) = qtrc(k,i,j) - ref_qv(k,i,j)
          enddo
          enddo
          enddo

          call prof_rapend  ("NumFilter_Main", 3)

       endif

       call calc_numdiff( work, iwork, & ! (out)
                          qv_diff, & ! (in)
                          nd_order, & ! (in)
                          0, 0, 0, ke )

    else ! iq /= I_QV

       call calc_numdiff( work, iwork, & ! (out)
                          qtrc, & ! (in)
                          nd_order, & ! (in)
                          0, 0, 0, ke )

    endif ! QV or not?


    call prof_rapstart("NumFilter_Main", 3)


    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js, je
    do i = is, ie
    do k = ks, ke-1
       num_diff_q(k,i,j,zdir) = work(k,i,j,zdir,iwork) * nd_coef_cdz(k) &
                              * 0.5_rp * ( dens(k+1,i,j)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff_q(1:ks-2,i,j,zdir) = 0.0_rp
       num_diff_q(ks-1,i,j,zdir) = work(ks-1,i,j,zdir,iwork) * nd_coef_cdz(ks-1) &
                                 * dens(ks,i,j)
       num_diff_q(ke  ,i,j,zdir) = work(ke  ,i,j,zdir,iwork) * nd_coef_cdz(ke  ) &
                                 * dens(ke,i,j)
       num_diff_q(ke+1:ka,i,j,zdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff_q(k,i,j,xdir) = work(k,i,j,xdir,iwork) * nd_coef_cdx(i) &
                              * 0.5_rp * ( dens(k,i+1,j)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff_q(1:ks-1,i,j,xdir) = 0.0_rp
       num_diff_q(ks  ,i,j,xdir) = num_diff_q(ks  ,i,j,xdir) * nd_sfc_fact
       num_diff_q(ks+1,i,j,xdir) = num_diff_q(ks+1,i,j,xdir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff_q(ke+1:ka,i,j,xdir) = 0.0_rp
    enddo
    enddo

    do j = js, je
    do i = is, ie
    do k = ks, ke
       num_diff_q(k,i,j,ydir) = work(k,i,j,ydir,iwork) * nd_coef_cdy(j) &
                              * 0.5_rp * ( dens(k,i,j+1)+dens(k,i,j) )
    enddo
    enddo
    enddo
    do j = js, je
    do i = is, ie
       num_diff_q(1:ks-1,i,j,ydir) = 0.0_rp
       num_diff_q(ks  ,i,j,ydir) = num_diff_q(ks  ,i,j,ydir) * nd_sfc_fact
       num_diff_q(ks+1,i,j,ydir) = num_diff_q(ks+1,i,j,ydir) * (1.0_rp + nd_sfc_fact) * 0.5_rp
       num_diff_q(ke+1:ka,i,j,ydir) = 0.0_rp
    enddo
    enddo

    call prof_rapend  ("NumFilter_Main", 3)

    call prof_rapstart("NumFilter_Comm", 3)

    call comm_vars8( num_diff_q(:,:,:,zdir), i_comm_qtrc_z )
    call comm_vars8( num_diff_q(:,:,:,xdir), i_comm_qtrc_x )
    call comm_vars8( num_diff_q(:,:,:,ydir), i_comm_qtrc_y )

    call comm_wait ( num_diff_q(:,:,:,zdir), i_comm_qtrc_z )
    call comm_wait ( num_diff_q(:,:,:,xdir), i_comm_qtrc_x )
    call comm_wait ( num_diff_q(:,:,:,ydir), i_comm_qtrc_y )

    call prof_rapend  ("NumFilter_Comm", 3)

    return

Here is the call graph for this function:

Here is the caller graph for this function:

atmos_dyn_filter_tend()

subroutine, public scale_atmos_dyn_common::atmos_dyn_filter_tend	(	real(rp), dimension(ka,ia,ja), intent(out)	phi_t,
		real(rp), dimension (ka,ia,ja), intent(in)	phi,
		real(rp), dimension(:), intent(in)	rdz,
		real(rp), dimension(:), intent(in)	rdx,
		real(rp), dimension(:), intent(in)	rdy,
		integer, intent(in)	KO,
		integer, intent(in)	IO,
		integer, intent(in)	JO
	)

Definition at line 1143 of file scale_atmos_dyn_common.F90.

References calc_diff3(), scale_grid_index::ie, scale_grid_index::is, scale_grid_index::je, scale_grid_index::js, scale_grid_index::ke, scale_grid_index::ks, scale_grid_index::xdir, scale_grid_index::ydir, and scale_grid_index::zdir.

    use scale_comm, only: &
       comm_vars8, &
       comm_wait
    implicit none
    real(RP), intent(out) :: phi_t(ka,ia,ja)
    real(RP), intent(in ) :: phi  (ka,ia,ja)
    real(RP), intent(in ) :: rdz(:)
    real(RP), intent(in ) :: rdx(:)
    real(RP), intent(in ) :: rdy(:)
    integer , intent(in ) :: ko
    integer , intent(in ) :: io
    integer , intent(in ) :: jo

    real(RP) :: flux(ka,ia,ja,3)

    integer :: k, i, j

    call calc_diff3( flux, & ! (out)
                     phi, & ! (in)
                     ko, io, jo )

    call comm_vars8( flux(:,:,:,xdir), 1 )
    call comm_vars8( flux(:,:,:,ydir), 2 )
    call comm_wait ( flux(:,:,:,xdir), 1 )
    call comm_wait ( flux(:,:,:,ydir), 2 )

    do j = js, je
    do i = is, ie
    do k = ks, ke
       phi_t(k,i,j) = ( flux(k+ko,i,j,zdir) - flux(k-1+ko,i,j,zdir) ) * rdz(k) &
                    + ( flux(k,i+io,j,xdir) - flux(k,i-1+io,j,xdir) ) * rdx(i) &
                    + ( flux(k,i,j+jo,ydir) - flux(k,i,j-1+jo,ydir) ) * rdy(j)
    end do
    end do
    end do

    return

Here is the call graph for this function:

atmos_dyn_copy_boundary()

subroutine, public scale_atmos_dyn_common::atmos_dyn_copy_boundary	(	real(rp), dimension (ka,ia,ja), intent(inout)	DENS,
		real(rp), dimension (ka,ia,ja), intent(inout)	MOMZ,
		real(rp), dimension (ka,ia,ja), intent(inout)	MOMX,
		real(rp), dimension (ka,ia,ja), intent(inout)	MOMY,
		real(rp), dimension (ka,ia,ja), intent(inout)	RHOT,
		real(rp), dimension (ka,ia,ja,va), intent(inout)	PROG,
		real(rp), dimension(ka,ia,ja), intent(in)	DENS0,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMZ0,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMX0,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMY0,
		real(rp), dimension(ka,ia,ja), intent(in)	RHOT0,
		real(rp), dimension(ka,ia,ja,va), intent(in)	PROG0,
		logical, intent(in)	BND_W,
		logical, intent(in)	BND_E,
		logical, intent(in)	BND_S,
		logical, intent(in)	BND_N
	)

Definition at line 1187 of file scale_atmos_dyn_common.F90.

References scale_grid_index::ia, scale_grid_index::ie, scale_grid_index::is, scale_grid_index::ja, scale_grid_index::je, scale_grid_index::js, scale_grid_index::ke, scale_grid_index::ks, and scale_index::va.

Referenced by scale_atmos_dyn_tinteg_short_rk3::atmos_dyn_tinteg_short_rk3(), and scale_atmos_dyn_tinteg_short_rk4::atmos_dyn_tinteg_short_rk4().

    implicit none
    real(RP), intent(inout) :: dens (ka,ia,ja)
    real(RP), intent(inout) :: momz (ka,ia,ja)
    real(RP), intent(inout) :: momx (ka,ia,ja)
    real(RP), intent(inout) :: momy (ka,ia,ja)
    real(RP), intent(inout) :: rhot (ka,ia,ja)
    real(RP), intent(inout) :: prog (ka,ia,ja,va)
    real(RP), intent(in)    :: dens0(ka,ia,ja)
    real(RP), intent(in)    :: momz0(ka,ia,ja)
    real(RP), intent(in)    :: momx0(ka,ia,ja)
    real(RP), intent(in)    :: momy0(ka,ia,ja)
    real(RP), intent(in)    :: rhot0(ka,ia,ja)
    real(RP), intent(in)    :: prog0(ka,ia,ja,va)
    logical,  intent(in)    :: bnd_w
    logical,  intent(in)    :: bnd_e
    logical,  intent(in)    :: bnd_s
    logical,  intent(in)    :: bnd_n

    integer :: k, i, j, iv

    if ( bnd_w ) then
       !$omp parallel do private(j,k) OMP_SCHEDULE_ collapse(2)
!OCL XFILL
       do j = 1, ja
       do i = 1, is-1
       do k = ks, ke
          dens(k,i,j) = dens0(k,i,j)
          momz(k,i,j) = momz0(k,i,j)
          momx(k,i,j) = momx0(k,i,j)
          momy(k,i,j) = momy0(k,i,j)
          rhot(k,i,j) = rhot0(k,i,j)
          do iv = 1, va
             prog(k,i,j,iv) = prog0(k,i,j,iv)
          end do
       enddo
       enddo
       enddo
    end if
    if ( bnd_e ) then
       !$omp parallel do private(j,k) OMP_SCHEDULE_ collapse(2)
!OCL XFILL
       do j = 1, ja
       do i = ie+1, ia
       do k = ks, ke
          dens(k,i,j) = dens0(k,i,j)
          momz(k,i,j) = momz0(k,i,j)
          momx(k,i,j) = momx0(k,i,j)
          momy(k,i,j) = momy0(k,i,j)
          rhot(k,i,j) = rhot0(k,i,j)
          do iv = 1, va
             prog(k,i,j,iv) = prog0(k,i,j,iv)
          end do
       enddo
       enddo
       enddo
       !$omp parallel do private(j,k) OMP_SCHEDULE_ collapse(2)
!OCL XFILL
       do j = 1, ja
       do k = ks, ke
          momx(k,ie,j) = momx0(k,ie,j)
       enddo
       enddo
    end if
    if ( bnd_s ) then
       !$omp parallel do private(j,k) OMP_SCHEDULE_ collapse(2)
!OCL XFILL
       do j = 1, js-1
       do i = 1, ia
       do k = ks, ke
          dens(k,i,j) = dens0(k,i,j)
          momz(k,i,j) = momz0(k,i,j)
          momx(k,i,j) = momx0(k,i,j)
          momy(k,i,j) = momy0(k,i,j)
          rhot(k,i,j) = rhot0(k,i,j)
          do iv = 1, va
             prog(k,i,j,iv) = prog0(k,i,j,iv)
          end do
       enddo
       enddo
       enddo
    end if
    if ( bnd_n ) then
       !$omp parallel do private(j,k) OMP_SCHEDULE_ collapse(2)
!OCL XFILL
       do j = je+1, ja
       do i = 1, ia
       do k = ks, ke
          dens(k,i,j) = dens0(k,i,j)
          momz(k,i,j) = momz0(k,i,j)
          momx(k,i,j) = momx0(k,i,j)
          momy(k,i,j) = momy0(k,i,j)
          rhot(k,i,j) = rhot0(k,i,j)
          do iv = 1, va
             prog(k,i,j,iv) = prog0(k,i,j,iv)
          end do
       enddo
       enddo
       enddo
       !$omp parallel do private(i,k) OMP_SCHEDULE_ collapse(2)
!OCL XFILL
       do i = 1, ia
       do k = ks, ke
          momy(k,i,je) = momy0(k,i,je)
       enddo
       enddo
    end if

    return

Here is the caller graph for this function:

atmos_dyn_divergence()

subroutine, public scale_atmos_dyn_common::atmos_dyn_divergence	(	real(rp), dimension(ka,ia,ja), intent(out)	DDIV,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMZ,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMX,
		real(rp), dimension(ka,ia,ja), intent(in)	MOMY,
		real(rp), dimension(ka,ia,ja,7), intent(in)	GSQRT,
		real(rp), dimension(ka,ia,ja,7), intent(in)	J13G,
		real(rp), dimension(ka,ia,ja,7), intent(in)	J23G,
		real(rp), intent(in)	J33G,
		real(rp), dimension(ia,ja,2,7), intent(in)	MAPF,
		real(rp), dimension(ka), intent(in)	RCDZ,
		real(rp), dimension(ia), intent(in)	RCDX,
		real(rp), dimension(ja), intent(in)	RCDY,
		real(rp), dimension(ka-1), intent(in)	RFDZ,
		real(rp), dimension(ka-1), intent(in)	FDZ
	)

Definition at line 1303 of file scale_atmos_dyn_common.F90.

References scale_gridtrans::i_uy, scale_gridtrans::i_uyz, scale_gridtrans::i_xv, scale_gridtrans::i_xvz, scale_gridtrans::i_xy, scale_gridtrans::i_xyw, scale_gridtrans::i_xyz, scale_grid_index::ie, scale_grid_index::is, scale_grid_index::je, scale_grid_index::js, scale_grid_index::ke, scale_grid_index::ks, scale_prof::prof_rapend(), and scale_prof::prof_rapstart().

Referenced by scale_atmos_dyn_tstep_large_fvm_heve::atmos_dyn_tstep_large_fvm_heve().

    use scale_gridtrans, only: &
       i_xyz, &
       i_xyw, &
       i_uyz, &
       i_xvz, &
       i_xy,  &
       i_uy,  &
       i_xv
    implicit none
    real(RP), intent(out) :: ddiv(ka,ia,ja)
    real(RP), intent(in)  :: momz(ka,ia,ja)
    real(RP), intent(in)  :: momx(ka,ia,ja)
    real(RP), intent(in)  :: momy(ka,ia,ja)
    real(RP), intent(in)  :: gsqrt(ka,ia,ja,7)
    real(RP), intent(in)  :: j13g(ka,ia,ja,7)
    real(RP), intent(in)  :: j23g(ka,ia,ja,7)
    real(RP), intent(in)  :: j33g
    real(RP), intent(in)  :: mapf(ia,ja,2,7)
    real(RP), intent(in)  :: rcdz(ka)
    real(RP), intent(in)  :: rcdx(ia)
    real(RP), intent(in)  :: rcdy(ja)
    real(RP), intent(in)  :: rfdz(ka-1)
    real(RP), intent(in)  :: fdz(ka-1)
    
    integer :: k, i, j

    call prof_rapstart("DYN_divercence", 2)

    ! 3D divergence

    !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
    do j = js, je+1
    do i = is, ie+1
    do k = ks-1, ke+1
       ddiv(k,i,j) = j33g * ( momz(k,i,j) - momz(k-1,i  ,j  ) ) * rcdz(k) &
                   + ( ( momx(k+1,i,j) + momx(k+1,i-1,j  ) ) * j13g(k+1,i,j,i_xyw) &
                     - ( momx(k-1,i,j) + momx(k-1,i-1,j  ) ) * j13g(k-1,i,j,i_xyw) &
                     + ( momy(k+1,i,j) + momy(k+1,i  ,j-1) ) * j23g(k+1,i,j,i_xyw) &
                     - ( momy(k-1,i,j) + momy(k-1,i  ,j-1) ) * j23g(k-1,i,j,i_xyw) ) / ( fdz(k)+fdz(k-1) ) &
                   + mapf(i,j,1,i_xy) * mapf(i,j,2,i_xy) &
                   * ( ( momx(k,i  ,j  ) * gsqrt(k,i  ,j  ,i_uyz) / mapf(i  ,j  ,2,i_uy) &
                       - momx(k,i-1,j  ) * gsqrt(k,i-1,j  ,i_uyz) / mapf(i-1,j  ,2,i_uy) ) * rcdx(i) &
                     + ( momy(k,i  ,j  ) * gsqrt(k,i  ,j  ,i_xvz) / mapf(i  ,j  ,1,i_xv) &
                       - momy(k,i,  j-1) * gsqrt(k,i  ,j-1,i_xvz) / mapf(i  ,j-1,1,i_xv) ) * rcdy(j) )
    enddo
    enddo
    enddo
#ifdef DEBUG
    k = iundef; i = iundef; j = iundef
#endif
    !$omp parallel do private(i,j) OMP_SCHEDULE_ collapse(2)
    do j = js, je+1
    do i = is, ie+1
       ddiv(ks,i,j) = j33g * ( momz(ks,i,j) ) * rcdz(ks) &
                    + ( ( momx(ks+1,i,j) + momx(ks+1,i-1,j  ) ) * j13g(ks+1,i,j,i_xyw) &
                      - ( momx(ks-1,i,j) + momx(ks  ,i-1,j  ) ) * j13g(ks  ,i,j,i_xyw) &
                      + ( momy(ks+1,i,j) + momy(ks+1,i  ,j-1) ) * j23g(ks+1,i,j,i_xyw) &
                      - ( momy(ks  ,i,j) + momy(ks  ,i  ,j-1) ) * j23g(ks  ,i,j,i_xyw) ) * rfdz(ks) &
                    + mapf(i,j,1,i_xy) * mapf(i,j,2,i_xy) &
                    * ( ( momx(ks,i  ,j  ) * gsqrt(ks,i  ,j  ,i_uyz) / mapf(i  ,j  ,2,i_uy) &
                        - momx(ks,i-1,j  ) * gsqrt(ks,i-1,j  ,i_uyz) / mapf(i-1,j  ,2,i_uy) ) * rcdx(i) &
                      + ( momy(ks,i  ,j  ) * gsqrt(ks,i  ,j  ,i_xvz) / mapf(i  ,j  ,1,i_xv) &
                        - momy(ks,i,  j-1) * gsqrt(ks,i  ,j-1,i_xvz) / mapf(i  ,j-1,1,i_xv) ) * rcdy(j) )
       ddiv(ke,i,j) = j33g * ( - momz(ke-1,i  ,j  ) ) * rcdz(ke) &
                    + ( ( momx(ke  ,i,j) + momx(ke  ,i-1,j  ) ) * j13g(ke  ,i,j,i_xyw) &
                      - ( momx(ke-1,i,j) + momx(ke-1,i-1,j  ) ) * j13g(ke-1,i,j,i_xyw) &
                      + ( momy(ke  ,i,j) + momy(ke  ,i  ,j-1) ) * j23g(ke  ,i,j,i_xyw) &
                      - ( momy(ke-1,i,j) + momy(ke-1,i  ,j-1) ) * j23g(ke-1,i,j,i_xyw) ) * rfdz(ke) &
                    + mapf(i,j,1,i_xy) * mapf(i,j,2,i_xy) &
                    * ( ( momx(ke,i  ,j  ) * gsqrt(ke,i  ,j  ,i_uyz) / mapf(i  ,j  ,2,i_uy) &
                        - momx(ke,i-1,j  ) * gsqrt(ke,i-1,j  ,i_uyz) / mapf(i-1,j  ,2,i_uy) ) * rcdx(i) &
                      + ( momy(ke,i  ,j  ) * gsqrt(ke,i  ,j  ,i_xvz) / mapf(i  ,j  ,1,i_xv) &
                        - momy(ke,i,  j-1) * gsqrt(ke,i  ,j-1,i_xvz) / mapf(i  ,j-1,1,i_xv) ) * rcdy(j) )
    enddo
    enddo
#ifdef DEBUG
    k = iundef; i = iundef; j = iundef
#endif
    call prof_rapend  ("DYN_divercence", 2)

    return

Here is the call graph for this function:

Here is the caller graph for this function:

calc_numdiff()

subroutine scale_atmos_dyn_common::calc_numdiff	(	real(rp), dimension(ka,ia,ja,3,2), intent(out)	work,
		integer, intent(out)	iwork,
		real(rp), dimension(ka,ia,ja), intent(in)	data,
		integer, intent(in)	nd_order,
		integer, intent(in)	KO,
		integer, intent(in)	IO,
		integer, intent(in)	JO,
		integer, intent(in)	KEE
	)

Definition at line 1392 of file scale_atmos_dyn_common.F90.

References calc_diff3(), scale_prof::prof_rapend(), scale_prof::prof_rapstart(), scale_grid_index::xdir, scale_grid_index::ydir, and scale_grid_index::zdir.

Referenced by atmos_dyn_numfilter_coef(), and atmos_dyn_numfilter_coef_q().

    use scale_comm, only: &
       comm_vars8, &
       comm_wait
    implicit none
    real(RP), intent(out) :: work(ka,ia,ja,3,2)
    integer,  intent(out) :: iwork
    real(RP), intent(in)  :: data(ka,ia,ja)
    integer,  intent(in)  :: nd_order
    integer,  intent(in)  :: ko
    integer,  intent(in)  :: io
    integer,  intent(in)  :: jo
    integer,  intent(in)  :: kee

    integer :: i_in, i_out, i_tmp

    integer :: no

    call prof_rapstart("NumFilter_Main", 3)

    call calc_diff3( work(:,:,:,:,1), & ! (out)
                     data, & ! (in)
                     ko, io, jo ) ! (in)

    call prof_rapend  ("NumFilter_Main", 3)

    !###########################################################################
    ! High order coefficients
    !###########################################################################

    i_in  = 1
    i_out = 2

    do no = 2, nd_order

       call prof_rapstart("NumFilter_Comm", 3)

       call comm_vars8( work(:,:,:,zdir,i_in),  16 )
       call comm_vars8( work(:,:,:,xdir,i_in),  17 )
       call comm_vars8( work(:,:,:,ydir,i_in),  18 )

       call comm_wait ( work(:,:,:,zdir,i_in),  16 )
       call comm_wait ( work(:,:,:,xdir,i_in),  17 )
       call comm_wait ( work(:,:,:,ydir,i_in),  18 )

       call prof_rapend  ("NumFilter_Comm", 3)

       call prof_rapstart("NumFilter_Main", 3)

       call calc_diff4( work(:,:,:,:,i_out), & ! (out)
                        work(:,:,:,:,i_in),  & ! (in)
                        cnz4(:,:,1+ko),      & ! (in)
                        cnx4(:,:,1+io),      & ! (in)
                        cny4(:,:,1+jo),      & ! (in)
                        kee                  ) ! (in)

       call prof_rapend  ("NumFilter_Main", 3)

       ! swap pointer target
       i_tmp = i_in
       i_in  = i_out
       i_out = i_tmp
    enddo

    iwork = i_in

    return

Here is the call graph for this function:

Here is the caller graph for this function:

calc_diff3()

subroutine scale_atmos_dyn_common::calc_diff3	(	real(rp), dimension(ka,ia,ja,3), intent(out)	diff,
		real(rp), dimension(ka,ia,ja), intent(in)	phi,
		integer, intent(in)	KO,
		integer, intent(in)	IO,
		integer, intent(in)	JO
	)

Definition at line 1465 of file scale_atmos_dyn_common.F90.

References scale_debug::check(), scale_grid_index::ie, scale_grid_index::is, scale_grid_index::je, scale_grid_index::js, scale_grid_index::ka, scale_grid_index::ke, scale_grid_index::ks, scale_grid_index::xdir, scale_grid_index::ydir, and scale_grid_index::zdir.

Referenced by atmos_dyn_filter_tend(), and calc_numdiff().

    implicit none
    real(RP), intent(out) :: diff(ka,ia,ja,3)
    real(RP), intent(in ) :: phi(ka,ia,ja)
    integer , intent(in ) :: ko
    integer , intent(in ) :: io
    integer , intent(in ) :: jo

    integer :: kee
    integer :: k, i, j

    kee = ke-ko

    if ( ko == 0 ) then

      !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
       do k = ks+1, ke-2
#ifdef DEBUG
          call check( __line__, phi(k+2,i,j) )
          call check( __line__, phi(k+1,i,j) )
          call check( __line__, phi(k  ,i,j) )
          call check( __line__, phi(k-1,i,j) )
#endif
          diff(k,i,j,zdir) = ( + cnz3(1,k+1,1) * phi(k+2,i,j) &
                               - cnz3(2,k+1,1) * phi(k+1,i,j) &
                               + cnz3(3,k+1,1) * phi(k  ,i,j) &
                               - cnz3(1,k  ,1) * phi(k-1,i,j) )
       enddo
       enddo
       enddo

       !$omp parallel do private(i,j) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
#ifdef DEBUG
          call check( __line__, phi(ks+2,i,j) )
          call check( __line__, phi(ks+1,i,j) )
          call check( __line__, phi(ks,i,j) )
          call check( __line__, phi(ke,i,j) )
          call check( __line__, phi(ke-1,i,j) )
          call check( __line__, phi(ke-2,i,j) )
#endif
          diff(ks,i,j,zdir) = ( + cnz3(1,ks+1,1) * phi(ks+2,i,j) &
                                - cnz3(2,ks+1,1) * phi(ks+1,i,j) &
                                + cnz3(3,ks+1,1) * phi(ks  ,i,j) &
                                - cnz3(1,ks  ,1) * phi(ks+1,i,j) )
          diff(ks-1,i,j,zdir) = - diff(ks  ,i,j,zdir)
          diff(ks-2,i,j,zdir) = - diff(ks+1,i,j,zdir)
          diff(ke-1,i,j,zdir) = ( + cnz3(1,ke  ,1) * phi(ke-1,i,j) &
                                  - cnz3(2,ke  ,1) * phi(ke  ,i,j) &
                                  + cnz3(3,ke  ,1) * phi(ke-1,i,j) &
                                  - cnz3(1,ke-1,1) * phi(ke-2,i,j) )
          diff(ke  ,i,j,zdir) = - diff(ke-1,i,j,zdir)
          diff(ke+1,i,j,zdir) = - diff(ke-2,i,j,zdir)
          diff(ke+2,i,j,zdir) = 0.0_rp
       end do
       end do

    else ! K0=1

       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
       do k = ks+2, ke-2
#ifdef DEBUG
          call check( __line__, phi(k+1,i,j) )
          call check( __line__, phi(k  ,i,j) )
          call check( __line__, phi(k-1,i,j) )
          call check( __line__, phi(k-2,i,j) )
#endif
          diff(k,i,j,zdir) = ( + cnz3(1,k  ,2) * phi(k+1,i,j) &
                               - cnz3(2,k  ,2) * phi(k  ,i,j) &
                               + cnz3(3,k  ,2) * phi(k-1,i,j) &
                               - cnz3(1,k-1,2) * phi(k-2,i,j) )
       enddo
       enddo
       enddo

       !$omp parallel do private(i,j) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
#ifdef DEBUG
          call check( __line__, phi(ks+2,i,j) )
          call check( __line__, phi(ks+1,i,j) )
          call check( __line__, phi(ks,i,j) )
          call check( __line__, phi(ks+1,i,j) )
          call check( __line__, phi(ks  ,i,j) )
          call check( __line__, phi(ke-1,i,j) )
          call check( __line__, phi(ke-2,i,j) )
          call check( __line__, phi(ke-3,i,j) )
#endif
          diff(ks+1,i,j,zdir) = ( + cnz3(1,ks+1,2) * phi(ks+2,i,j) &
                                  - cnz3(2,ks+1,2) * phi(ks+1,i,j) &
                                  + cnz3(3,ks+1,2) * phi(ks  ,i,j) )
          diff(ks  ,i,j,zdir) = ( + cnz3(1,ks  ,2) * phi(ks+1,i,j) &
                                  - cnz3(2,ks  ,2) * phi(ks  ,i,j) &
                                  - cnz3(1,ks-1,2) * phi(ks+1,i,j) )
          diff(ks-1,i,j,zdir) = - diff(ks  ,i,j,zdir)
          diff(ks-2,i,j,zdir) = - diff(ks+1,i,j,zdir)
          diff(ke-1,i,j,zdir) = ( - cnz3(2,ke-1,2) * phi(ke-1,i,j) &
                                  + cnz3(3,ke-1,2) * phi(ke-2,i,j) &
                                  - cnz3(1,ke-2,2) * phi(ke-3,i,j) )
          diff(ke  ,i,j,zdir) = ( + cnz3(1,ke  ,2) * phi(ke-1,i,j) &
                                  + cnz3(3,ke  ,2) * phi(ke-1,i,j) &
                                  - cnz3(1,ke-1,2) * phi(ke-2,i,j) )
          diff(ke+1,i,j,zdir) = - diff(ke  ,i,j,zdir)
          diff(ke+2,i,j,zdir) = - diff(ke-1,i,j,zdir)
       end do
       end do

    end if

    if ( io == 0 ) then
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
       do k = ks, kee
#ifdef DEBUG
          call check( __line__, phi(k,i+2,j) )
          call check( __line__, phi(k,i+1,j) )
          call check( __line__, phi(k,i  ,j) )
          call check( __line__, phi(k,i-1,j) )
#endif
          diff(k,i,j,xdir) = ( + cnx3(1,i+1,1) * phi(k,i+2,j) &
                               - cnx3(2,i+1,1) * phi(k,i+1,j) &
                               + cnx3(3,i+1,1) * phi(k,i  ,j) &
                               - cnx3(1,i  ,1) * phi(k,i-1,j) )
       enddo
       enddo
       enddo
    else
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
       do k = ks, kee
#ifdef DEBUG
          call check( __line__, phi(k,i+1,j) )
          call check( __line__, phi(k,i  ,j) )
          call check( __line__, phi(k,i-1,j) )
          call check( __line__, phi(k,i-2,j) )
#endif
          diff(k,i,j,xdir) = ( + cnx3(1,i  ,2) * phi(k,i+1,j) &
                               - cnx3(2,i  ,2) * phi(k,i  ,j) &
                               + cnx3(3,i  ,2) * phi(k,i-1,j) &
                               - cnx3(1,i-1,2) * phi(k,i-2,j) )
       enddo
       enddo
       enddo
    end if

    !$omp parallel do private(i,j) OMP_SCHEDULE_ collapse(2)
    do j = js, je
    do i = is, ie
       diff(   1:ks-1,i,j,xdir) = 0.0_rp
       diff(ke+1:ka  ,i,j,xdir) = 0.0_rp
    enddo
    enddo

    if ( jo == 0 ) then
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
       do k = ks, kee
#ifdef DEBUG
          call check( __line__, phi(k,i,j+2) )
          call check( __line__, phi(k,i,j+1) )
          call check( __line__, phi(k,i,j  ) )
          call check( __line__, phi(k,i,j-1) )
#endif
          diff(k,i,j,ydir) = ( + cny3(1,j+1,1) * phi(k,i,j+2) &
                               - cny3(2,j+1,1) * phi(k,i,j+1) &
                               + cny3(3,j+1,1) * phi(k,i,j  ) &
                               - cny3(1,j  ,1) * phi(k,i,j-1) )
       enddo
       enddo
       enddo
    else
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = js, je
       do i = is, ie
       do k = ks, kee
#ifdef DEBUG
          call check( __line__, phi(k,i,j+1) )
          call check( __line__, phi(k,i,j  ) )
          call check( __line__, phi(k,i,j-1) )
          call check( __line__, phi(k,i,j-2) )
#endif
          diff(k,i,j,ydir) = ( + cny3(1,j  ,2) * phi(k,i,j+1) &
                               - cny3(2,j  ,2) * phi(k,i,j  ) &
                               + cny3(3,j  ,2) * phi(k,i,j-1) &
                               - cny3(1,j-1,2) * phi(k,i,j-2) )
       enddo
       enddo
       enddo
    end if

    !$omp parallel do private(i,j) OMP_SCHEDULE_ collapse(2)
    do j = js, je
    do i = is, ie
       diff(   1:ks-1,i,j,ydir) = 0.0_rp
       diff(ke+1:ka  ,i,j,ydir) = 0.0_rp
    enddo
    enddo

    return

Here is the call graph for this function:

Here is the caller graph for this function:

atmos_dyn_fct()

subroutine, public scale_atmos_dyn_common::atmos_dyn_fct	(	real(rp), dimension(ka,ia,ja,3), intent(out)	qflx_anti,
		real(rp), dimension(ka,ia,ja), intent(in)	phi_in,
		real(rp), dimension(ka,ia,ja), intent(in)	DENS0,
		real(rp), dimension (ka,ia,ja), intent(in)	DENS,
		real(rp), dimension(ka,ia,ja,3), intent(in)	qflx_hi,
		real(rp), dimension(ka,ia,ja,3), intent(in)	qflx_lo,
		real(rp), dimension(ka,ia,ja,3), intent(in)	mflx_hi,
		real(rp), dimension(:), intent(in)	rdz,
		real(rp), dimension(:), intent(in)	rdx,
		real(rp), dimension(:), intent(in)	rdy,
		real(rp), dimension(ka,ia,ja), intent(in)	GSQRT,
		real(rp), dimension(ia,ja,2), intent(in)	MAPF,
		real(rp), intent(in)	dt,
		logical, intent(in)	flag_vect
	)

Flux Correction Transport Limiter.

Parameters

[in]	gsqrt	vertical metrics {G}^1/2
[in]	mapf	map factor

Definition at line 1794 of file scale_atmos_dyn_common.F90.

References scale_debug::check(), scale_const::const_eps, scale_const::const_undef, scale_const::const_undef2, scale_grid_index::iblock, scale_grid_index::ie, scale_grid_index::is, scale_grid_index::jblock, scale_grid_index::je, scale_grid_index::js, scale_grid_index::ke, scale_grid_index::ks, scale_grid_index::xdir, scale_grid_index::ydir, and scale_grid_index::zdir.

Referenced by scale_atmos_dyn_tinteg_large_euler::atmos_dyn_tinteg_large_euler(), scale_atmos_dyn_tinteg_large_rk3::atmos_dyn_tinteg_large_rk3(), scale_atmos_dyn_tstep_large_fvm_heve::atmos_dyn_tstep_large_fvm_heve(), scale_atmos_dyn_tstep_short_fvm_heve::atmos_dyn_tstep_short_fvm_heve(), scale_atmos_dyn_tstep_short_fvm_hevi::atmos_dyn_tstep_short_fvm_hevi(), scale_atmos_dyn_tstep_short_fvm_hivi::atmos_dyn_tstep_short_fvm_hivi(), and scale_atmos_dyn_tstep_tracer_fvm_heve::atmos_dyn_tstep_tracer_fvm_heve().

    use scale_const, only: &
       undef => const_undef, &
       iundef => const_undef2, &
       epsilon => const_eps
    use scale_comm, only: &
       comm_vars8, &
       comm_wait
    implicit none

    real(RP), intent(out) :: qflx_anti(ka,ia,ja,3)

    real(RP), intent(in) :: phi_in(ka,ia,ja) ! physical quantity
    real(RP), intent(in) :: dens0(ka,ia,ja)
    real(RP), intent(in) :: dens (ka,ia,ja)

    real(RP), intent(in) :: qflx_hi(ka,ia,ja,3)
    real(RP), intent(in) :: qflx_lo(ka,ia,ja,3)
    real(RP), intent(in) :: mflx_hi(ka,ia,ja,3)

    real(RP), intent(in) :: rdz(:)
    real(RP), intent(in) :: rdx(:)
    real(RP), intent(in) :: rdy(:)

    real(RP), intent(in) :: gsqrt(ka,ia,ja)
    real(RP), intent(in) :: mapf(ia,ja,2)

    real(RP), intent(in) :: dt

    logical, intent(in) :: flag_vect

    ! work for FCT
    real(RP) :: phi_lo(ka,ia,ja)
    real(RP) :: pjpls(ka,ia,ja)
    real(RP) :: pjmns(ka,ia,ja)
    real(RP) :: qjpls(ka,ia,ja)
    real(RP) :: qjmns(ka,ia,ja)
    real(RP) :: rjpls(ka,ia,ja)
    real(RP) :: rjmns(ka,ia,ja)

    real(RP) :: qmin, qmax
    real(RP) :: zerosw, dirsw

    real(RP) :: fact(0:1,-1:1,-1:1)
    real(RP) :: rw, ru, rv
    real(RP) :: qa_in, qb_in
    real(RP) :: qa_lo, qb_lo

    integer :: k, i, j, ijs
    integer :: iis, iie, jjs, jje
    !---------------------------------------------------------------------------

#ifdef DEBUG
    qflx_anti(:,:,:,:) = undef

    pjpls(:,:,:) = undef
    pjmns(:,:,:) = undef
    qjpls(:,:,:) = undef
    qjmns(:,:,:) = undef
    rjpls(:,:,:) = undef
    rjmns(:,:,:) = undef
#endif

    do jjs = js, je, jblock
    jje = jjs+jblock-1
    do iis = is, ie, iblock
    iie = iis+iblock-1

       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
       do k = ks, ke-1
#ifdef DEBUG
          call check( __line__, qflx_hi(k,i,j,zdir) )
          call check( __line__, qflx_lo(k,i,j,zdir) )
#endif
          qflx_anti(k,i,j,zdir) = qflx_hi(k,i,j,zdir) - qflx_lo(k,i,j,zdir)
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
          qflx_anti(ks-1,i,j,zdir) = 0.0_rp
          qflx_anti(ke  ,i,j,zdir) = 0.0_rp
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = jjs  , jje
       do i = iis-1, iie
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, qflx_hi(k,i,j,xdir) )
          call check( __line__, qflx_lo(k,i,j,xdir) )
#endif
          qflx_anti(k,i,j,xdir) = qflx_hi(k,i,j,xdir) - qflx_lo(k,i,j,xdir)
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = jjs-1, jje
       do i = iis  , iie
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, qflx_hi(k,i,j,ydir) )
          call check( __line__, qflx_lo(k,i,j,ydir) )
#endif
          qflx_anti(k,i,j,ydir) = qflx_hi(k,i,j,ydir) - qflx_lo(k,i,j,ydir)
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

       !--- update monotone scheme
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = jjs-1, jje+1
       do i = iis-1, iie+1
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, phi_in(k,i,j) )
          call check( __line__, qflx_lo(k  ,i  ,j  ,zdir) )
          call check( __line__, qflx_lo(k-1,i  ,j  ,zdir) )
          call check( __line__, qflx_lo(k  ,i  ,j  ,xdir) )
          call check( __line__, qflx_lo(k  ,i-1,j  ,xdir) )
          call check( __line__, qflx_lo(k  ,i  ,j  ,ydir) )
          call check( __line__, qflx_lo(k  ,i  ,j-1,ydir) )
#endif
          phi_lo(k,i,j) = ( phi_in(k,i,j) * dens0(k,i,j) &
                          + dt * ( - ( ( qflx_lo(k,i,j,zdir)-qflx_lo(k-1,i  ,j  ,zdir) ) * rdz(k) &
                                     + ( qflx_lo(k,i,j,xdir)-qflx_lo(k  ,i-1,j  ,xdir) ) * rdx(i) &
                                     + ( qflx_lo(k,i,j,ydir)-qflx_lo(k  ,i  ,j-1,ydir) ) * rdy(j) &
                                     ) * mapf(i,j,1) * mapf(i,j,2) / gsqrt(k,i,j)                 ) &
                          ) / dens(k,i,j)
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

       !--- calc net incoming quantity change by antidiffusive flux
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, qflx_anti(k  ,i  ,j  ,zdir) )
          call check( __line__, qflx_anti(k-1,i  ,j  ,zdir) )
          call check( __line__, qflx_anti(k  ,i  ,j  ,xdir) )
          call check( __line__, qflx_anti(k  ,i-1,j  ,xdir) )
          call check( __line__, qflx_anti(k  ,i  ,j  ,ydir) )
          call check( __line__, qflx_anti(k  ,i  ,j-1,ydir) )
#endif
          pjpls(k,i,j) = dt * ( ( max(0.0_rp,qflx_anti(k-1,i  ,j  ,zdir)) - min(0.0_rp,qflx_anti(k,i,j,zdir)) ) * rdz(k) &
                              + ( max(0.0_rp,qflx_anti(k  ,i-1,j  ,xdir)) - min(0.0_rp,qflx_anti(k,i,j,xdir)) ) * rdx(i) &
                              + ( max(0.0_rp,qflx_anti(k  ,i  ,j-1,ydir)) - min(0.0_rp,qflx_anti(k,i,j,ydir)) ) * rdy(j) &
                              ) * mapf(i,j,1) * mapf(i,j,2) / gsqrt(k,i,j)
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

       !--- calc net outgoing quantity change by antidiffusive flux
       !$omp parallel do private(i,j,k) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, qflx_anti(k  ,i  ,j  ,zdir) )
          call check( __line__, qflx_anti(k-1,i  ,j  ,zdir) )
          call check( __line__, qflx_anti(k  ,i  ,j  ,xdir) )
          call check( __line__, qflx_anti(k  ,i-1,j  ,xdir) )
          call check( __line__, qflx_anti(k  ,i  ,j  ,ydir) )
          call check( __line__, qflx_anti(k  ,i  ,j-1,ydir) )
#endif
          pjmns(k,i,j) = dt * ( ( max(0.0_rp,qflx_anti(k,i,j,zdir)) - min(0.0_rp,qflx_anti(k-1,i  ,j  ,zdir)) ) * rdz(k) &
                              + ( max(0.0_rp,qflx_anti(k,i,j,xdir)) - min(0.0_rp,qflx_anti(k  ,i-1,j  ,xdir)) ) * rdx(i) &
                              + ( max(0.0_rp,qflx_anti(k,i,j,ydir)) - min(0.0_rp,qflx_anti(k  ,i  ,j-1,ydir)) ) * rdy(j) &
                              ) * mapf(i,j,1) * mapf(i,j,2) / gsqrt(k,i,j)
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

       !--- calc allowable range or quantity change by antidiffusive flux

       if (flag_vect) then

       !$omp parallel do private(i,j,k,rw,ru,rv,fact,qa_in,qb_in,qa_lo,qb_lo,qmax,qmin) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
       do k = ks+1, ke-1
          rw = (mflx_hi(k,i,j,zdir)+mflx_hi(k-1,i  ,j  ,zdir)) * rdz(k) ! 2 * rho * w / dz
          ru = (mflx_hi(k,i,j,xdir)+mflx_hi(k  ,i-1,j  ,xdir)) * rdx(i) ! 2 * rho * u / dx
          rv = (mflx_hi(k,i,j,ydir)+mflx_hi(k  ,i  ,j-1,ydir)) * rdy(j) ! 2 * rho * v / dy

          call get_fact_fct( fact, & ! (out)
                             rw, ru, rv ) ! (in)

          qa_in = fact(1, 1, 1) * phi_in(k+1,i+1,j+1) &
                + fact(0, 1, 1) * phi_in(k  ,i+1,j+1) &
                + fact(1, 0, 1) * phi_in(k+1,i  ,j+1) &
                + fact(0, 0, 1) * phi_in(k  ,i  ,j+1) &
                + fact(1,-1, 1) * phi_in(k+1,i-1,j+1) &
                + fact(1, 1, 0) * phi_in(k+1,i+1,j  ) &
                + fact(0, 1, 0) * phi_in(k  ,i+1,j  ) &
                + fact(1, 0, 0) * phi_in(k+1,i  ,j  ) &
                + fact(1,-1, 0) * phi_in(k+1,i-1,j  ) &
                + fact(1, 1,-1) * phi_in(k+1,i+1,j-1) &
                + fact(0, 1,-1) * phi_in(k  ,i+1,j-1) &
                + fact(1, 0,-1) * phi_in(k+1,i  ,j-1) &
                + fact(1,-1,-1) * phi_in(k+1,i-1,j-1) &
                + fact(0, 0, 0) * phi_in(k  ,i  ,j  )
          qb_in = fact(1, 1, 1) * phi_in(k-1,i-1,j-1) &
                + fact(0, 1, 1) * phi_in(k  ,i-1,j-1) &
                + fact(1, 0, 1) * phi_in(k-1,i  ,j-1) &
                + fact(0, 0, 1) * phi_in(k  ,i  ,j-1) &
                + fact(1,-1, 1) * phi_in(k-1,i+1,j-1) &
                + fact(1, 1, 0) * phi_in(k-1,i-1,j  ) &
                + fact(0, 1, 0) * phi_in(k  ,i-1,j  ) &
                + fact(1, 0, 0) * phi_in(k-1,i  ,j  ) &
                + fact(1,-1, 0) * phi_in(k-1,i+1,j  ) &
                + fact(1, 1,-1) * phi_in(k-1,i-1,j+1) &
                + fact(0, 1,-1) * phi_in(k  ,i-1,j-1) &
                + fact(1, 0,-1) * phi_in(k-1,i  ,j-1) &
                + fact(1,-1,-1) * phi_in(k-1,i+1,j+1) &
                + fact(0, 0, 0) * phi_in(k  ,i  ,j  )
          qa_lo = fact(1, 1, 1) * phi_lo(k+1,i+1,j+1) &
                + fact(0, 1, 1) * phi_lo(k  ,i+1,j+1) &
                + fact(1, 0, 1) * phi_lo(k+1,i  ,j+1) &
                + fact(0, 0, 1) * phi_lo(k  ,i  ,j+1) &
                + fact(1,-1, 1) * phi_lo(k+1,i-1,j+1) &
                + fact(1, 1, 0) * phi_lo(k+1,i+1,j  ) &
                + fact(0, 1, 0) * phi_lo(k  ,i+1,j  ) &
                + fact(1, 0, 0) * phi_lo(k+1,i  ,j  ) &
                + fact(1,-1, 0) * phi_lo(k+1,i-1,j  ) &
                + fact(1, 1,-1) * phi_lo(k+1,i+1,j-1) &
                + fact(0, 1,-1) * phi_lo(k  ,i+1,j-1) &
                + fact(1, 0,-1) * phi_lo(k+1,i  ,j-1) &
                + fact(1,-1,-1) * phi_lo(k+1,i-1,j-1) &
                + fact(0, 0, 0) * phi_lo(k  ,i  ,j  )
          qb_lo = fact(1, 1, 1) * phi_lo(k-1,i-1,j-1) &
                + fact(0, 1, 1) * phi_lo(k  ,i-1,j-1) &
                + fact(1, 0, 1) * phi_lo(k-1,i  ,j-1) &
                + fact(0, 0, 1) * phi_lo(k  ,i  ,j-1) &
                + fact(1,-1, 1) * phi_lo(k-1,i+1,j-1) &
                + fact(1, 1, 0) * phi_lo(k-1,i-1,j  ) &
                + fact(0, 1, 0) * phi_lo(k  ,i-1,j  ) &
                + fact(1, 0, 0) * phi_lo(k-1,i  ,j  ) &
                + fact(1,-1, 0) * phi_lo(k-1,i+1,j  ) &
                + fact(1, 1,-1) * phi_lo(k-1,i-1,j+1) &
                + fact(0, 1,-1) * phi_lo(k  ,i-1,j-1) &
                + fact(1, 0,-1) * phi_lo(k-1,i  ,j-1) &
                + fact(1,-1,-1) * phi_lo(k-1,i+1,j+1) &
                + fact(0, 0, 0) * phi_lo(k  ,i  ,j  )

          qmax = max( &
               phi_in(k,i,j), qa_in, qb_in, &
               phi_lo(k,i,j), qa_lo, qb_lo  )
          qmin = min( &
               phi_in(k,i,j), qa_in, qb_in, &
               phi_lo(k,i,j), qa_lo, qb_lo  )
          qjpls(k,i,j) = ( qmax - phi_lo(k,i,j) ) * dens(k,i,j)
          qjmns(k,i,j) = ( phi_lo(k,i,j) - qmin ) * dens(k,i,j)
       end do
       end do
       end do

       ! k = KS
       !$omp parallel do private(i,j,rw,ru,rv,fact,qa_in,qb_in,qa_lo,qb_lo,qmax,qmin) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
          rw = (mflx_hi(ks,i,j,zdir)                           ) * rdz(ks)! 2 * rho * w / dz
          ru = (mflx_hi(ks,i,j,xdir)+mflx_hi(ks  ,i-1,j  ,xdir)) * rdx(i) ! 2 * rho * u / dx
          rv = (mflx_hi(ks,i,j,ydir)+mflx_hi(ks  ,i  ,j-1,ydir)) * rdy(j) ! 2 * rho * v / dy

          call get_fact_fct( fact, & ! (out)
                             rw, ru, rv ) ! (in)

          qa_in = fact(1, 1, 1) * phi_in(ks+1,i+1,j+1) &
                + fact(0, 1, 1) * phi_in(ks  ,i+1,j+1) &
                + fact(1, 0, 1) * phi_in(ks+1,i  ,j+1) &
                + fact(0, 0, 1) * phi_in(ks  ,i  ,j+1) &
                + fact(1,-1, 1) * phi_in(ks+1,i-1,j+1) &
                + fact(1, 1, 0) * phi_in(ks+1,i+1,j  ) &
                + fact(0, 1, 0) * phi_in(ks  ,i+1,j  ) &
                + fact(1, 0, 0) * phi_in(ks+1,i  ,j  ) &
                + fact(1,-1, 0) * phi_in(ks+1,i-1,j  ) &
                + fact(1, 1,-1) * phi_in(ks+1,i+1,j-1) &
                + fact(0, 1,-1) * phi_in(ks  ,i+1,j-1) &
                + fact(1, 0,-1) * phi_in(ks+1,i  ,j-1) &
                + fact(1,-1,-1) * phi_in(ks+1,i-1,j-1) &
                + fact(0, 0, 0) * phi_in(ks  ,i  ,j  )
          qb_in = fact(1, 1, 1) * phi_in(ks  ,i-1,j-1) &
                + fact(0, 1, 1) * phi_in(ks  ,i-1,j-1) &
                + fact(1, 0, 1) * phi_in(ks  ,i  ,j-1) &
                + fact(0, 0, 1) * phi_in(ks  ,i  ,j-1) &
                + fact(1,-1, 1) * phi_in(ks  ,i+1,j-1) &
                + fact(1, 1, 0) * phi_in(ks  ,i-1,j  ) &
                + fact(0, 1, 0) * phi_in(ks  ,i-1,j  ) &
                + fact(1, 0, 0) * phi_in(ks  ,i  ,j  ) &
                + fact(1,-1, 0) * phi_in(ks  ,i+1,j  ) &
                + fact(1, 1,-1) * phi_in(ks  ,i-1,j+1) &
                + fact(0, 1,-1) * phi_in(ks  ,i-1,j-1) &
                + fact(1, 0,-1) * phi_in(ks  ,i  ,j-1) &
                + fact(1,-1,-1) * phi_in(ks  ,i+1,j+1) &
                + fact(0, 0, 0) * phi_in(ks  ,i  ,j  )
          qa_lo = fact(1, 1, 1) * phi_lo(ks+1,i+1,j+1) &
                + fact(0, 1, 1) * phi_lo(ks  ,i+1,j+1) &
                + fact(1, 0, 1) * phi_lo(ks+1,i  ,j+1) &
                + fact(0, 0, 1) * phi_lo(ks  ,i  ,j+1) &
                + fact(1,-1, 1) * phi_lo(ks+1,i-1,j+1) &
                + fact(1, 1, 0) * phi_lo(ks+1,i+1,j  ) &
                + fact(0, 1, 0) * phi_lo(ks  ,i+1,j  ) &
                + fact(1, 0, 0) * phi_lo(ks+1,i  ,j  ) &
                + fact(1,-1, 0) * phi_lo(ks+1,i-1,j  ) &
                + fact(1, 1,-1) * phi_lo(ks+1,i+1,j-1) &
                + fact(0, 1,-1) * phi_lo(ks  ,i+1,j-1) &
                + fact(1, 0,-1) * phi_lo(ks+1,i  ,j-1) &
                + fact(1,-1,-1) * phi_lo(ks+1,i-1,j-1) &
                + fact(0, 0, 0) * phi_lo(ks  ,i  ,j  )
          qb_lo = fact(1, 1, 1) * phi_lo(ks  ,i-1,j-1) &
                + fact(0, 1, 1) * phi_lo(ks  ,i-1,j-1) &
                + fact(1, 0, 1) * phi_lo(ks  ,i  ,j-1) &
                + fact(0, 0, 1) * phi_lo(ks  ,i  ,j-1) &
                + fact(1,-1, 1) * phi_lo(ks  ,i+1,j-1) &
                + fact(1, 1, 0) * phi_lo(ks  ,i-1,j  ) &
                + fact(0, 1, 0) * phi_lo(ks  ,i-1,j  ) &
                + fact(1, 0, 0) * phi_lo(ks  ,i  ,j  ) &
                + fact(1,-1, 0) * phi_lo(ks  ,i+1,j  ) &
                + fact(1, 1,-1) * phi_lo(ks  ,i-1,j+1) &
                + fact(0, 1,-1) * phi_lo(ks  ,i-1,j-1) &
                + fact(1, 0,-1) * phi_lo(ks  ,i  ,j-1) &
                + fact(1,-1,-1) * phi_lo(ks  ,i+1,j+1) &
                + fact(0, 0, 0) * phi_lo(ks  ,i  ,j  )

          qmax = max( &
               phi_in(ks,i,j), qa_in, qb_in, &
               phi_lo(ks,i,j), qa_lo, qb_lo  )
          qmin = min( &
               phi_in(ks,i,j), qa_in, qb_in, &
               phi_lo(ks,i,j), qa_lo, qb_lo  )
          qjpls(ks,i,j) = ( qmax - phi_lo(ks,i,j) ) * dens(ks,i,j)
          qjmns(ks,i,j) = ( phi_lo(ks,i,j) - qmin ) * dens(ks,i,j)
       end do
       end do

       ! k = KE
       !$omp parallel do private(i,j,rw,ru,rv,fact,qa_in,qb_in,qa_lo,qb_lo,qmax,qmin) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
          rw = (                     mflx_hi(ke-1,i  ,j  ,zdir)) * rdz(ke)! 2 * rho * w / dz
          ru = (mflx_hi(ke,i,j,xdir)+mflx_hi(ke  ,i-1,j  ,xdir)) * rdx(i) ! 2 * rho * u / dx
          rv = (mflx_hi(ke,i,j,ydir)+mflx_hi(ke  ,i  ,j-1,ydir)) * rdy(j) ! 2 * rho * v / dy

          call get_fact_fct( fact, & ! (out)
                             rw, ru, rv ) ! (in)

          qa_in = fact(1, 1, 1) * phi_in(ke  ,i+1,j+1) &
                + fact(0, 1, 1) * phi_in(ke  ,i+1,j+1) &
                + fact(1, 0, 1) * phi_in(ke  ,i  ,j+1) &
                + fact(0, 0, 1) * phi_in(ke  ,i  ,j+1) &
                + fact(1,-1, 1) * phi_in(ke  ,i-1,j+1) &
                + fact(1, 1, 0) * phi_in(ke  ,i+1,j  ) &
                + fact(0, 1, 0) * phi_in(ke  ,i+1,j  ) &
                + fact(1, 0, 0) * phi_in(ke  ,i  ,j  ) &
                + fact(1,-1, 0) * phi_in(ke  ,i-1,j  ) &
                + fact(1, 1,-1) * phi_in(ke  ,i+1,j-1) &
                + fact(0, 1,-1) * phi_in(ke  ,i+1,j-1) &
                + fact(1, 0,-1) * phi_in(ke  ,i  ,j-1) &
                + fact(1,-1,-1) * phi_in(ke  ,i-1,j-1) &
                + fact(0, 0, 0) * phi_in(ke  ,i  ,j  )
          qb_in = fact(1, 1, 1) * phi_in(ke-1,i-1,j-1) &
                + fact(0, 1, 1) * phi_in(ke  ,i-1,j-1) &
                + fact(1, 0, 1) * phi_in(ke-1,i  ,j-1) &
                + fact(0, 0, 1) * phi_in(ke  ,i  ,j-1) &
                + fact(1,-1, 1) * phi_in(ke-1,i+1,j-1) &
                + fact(1, 1, 0) * phi_in(ke-1,i-1,j  ) &
                + fact(0, 1, 0) * phi_in(ke  ,i-1,j  ) &
                + fact(1, 0, 0) * phi_in(ke-1,i  ,j  ) &
                + fact(1,-1, 0) * phi_in(ke-1,i+1,j  ) &
                + fact(1, 1,-1) * phi_in(ke-1,i-1,j+1) &
                + fact(0, 1,-1) * phi_in(ke  ,i-1,j-1) &
                + fact(1, 0,-1) * phi_in(ke-1,i  ,j-1) &
                + fact(1,-1,-1) * phi_in(ke-1,i+1,j+1) &
                + fact(0, 0, 0) * phi_in(ke  ,i  ,j  )
          qa_lo = fact(1, 1, 1) * phi_lo(ke  ,i+1,j+1) &
                + fact(0, 1, 1) * phi_lo(ke  ,i+1,j+1) &
                + fact(1, 0, 1) * phi_lo(ke  ,i  ,j+1) &
                + fact(0, 0, 1) * phi_lo(ke  ,i  ,j+1) &
                + fact(1,-1, 1) * phi_lo(ke  ,i-1,j+1) &
                + fact(1, 1, 0) * phi_lo(ke  ,i+1,j  ) &
                + fact(0, 1, 0) * phi_lo(ke  ,i+1,j  ) &
                + fact(1, 0, 0) * phi_lo(ke  ,i  ,j  ) &
                + fact(1,-1, 0) * phi_lo(ke  ,i-1,j  ) &
                + fact(1, 1,-1) * phi_lo(ke  ,i+1,j-1) &
                + fact(0, 1,-1) * phi_lo(ke  ,i+1,j-1) &
                + fact(1, 0,-1) * phi_lo(ke  ,i  ,j-1) &
                + fact(1,-1,-1) * phi_lo(ke  ,i-1,j-1) &
                + fact(0, 0, 0) * phi_lo(ke  ,i  ,j  )
          qb_lo = fact(1, 1, 1) * phi_lo(ke-1,i-1,j-1) &
                + fact(0, 1, 1) * phi_lo(ke  ,i-1,j-1) &
                + fact(1, 0, 1) * phi_lo(ke-1,i  ,j-1) &
                + fact(0, 0, 1) * phi_lo(ke  ,i  ,j-1) &
                + fact(1,-1, 1) * phi_lo(ke-1,i+1,j-1) &
                + fact(1, 1, 0) * phi_lo(ke-1,i-1,j  ) &
                + fact(0, 1, 0) * phi_lo(ke  ,i-1,j  ) &
                + fact(1, 0, 0) * phi_lo(ke-1,i  ,j  ) &
                + fact(1,-1, 0) * phi_lo(ke-1,i+1,j  ) &
                + fact(1, 1,-1) * phi_lo(ke-1,i-1,j+1) &
                + fact(0, 1,-1) * phi_lo(ke  ,i-1,j-1) &
                + fact(1, 0,-1) * phi_lo(ke-1,i  ,j-1) &
                + fact(1,-1,-1) * phi_lo(ke-1,i+1,j+1) &
                + fact(0, 0, 0) * phi_lo(ke  ,i  ,j  )

          qmax = max( &
               phi_in(ke,i,j), qa_in, qb_in, &
               phi_lo(ke,i,j), qa_lo, qb_lo  )
          qmin = min( &
               phi_in(ke,i,j), qa_in, qb_in, &
               phi_lo(ke,i,j), qa_lo, qb_lo  )
          qjpls(ke,i,j) = ( qmax - phi_lo(ke,i,j) ) * dens(ke,i,j)
          qjmns(ke,i,j) = ( phi_lo(ke,i,j) - qmin ) * dens(ke,i,j)
       end do
       end do

       else

       !$omp parallel do private(i,j,k,qmax,qmin) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
       do k = ks+1, ke-1
#ifdef DEBUG
          call check( __line__, phi_in(k  ,i  ,j  ) )
          call check( __line__, phi_in(k-1,i  ,j  ) )
          call check( __line__, phi_in(k+1,i  ,j  ) )
          call check( __line__, phi_in(k  ,i-1,j  ) )
          call check( __line__, phi_in(k  ,i+1,j  ) )
          call check( __line__, phi_in(k  ,i  ,j+1) )
          call check( __line__, phi_in(k  ,i  ,j-1) )
          call check( __line__, phi_lo(k  ,i  ,j  ) )
          call check( __line__, phi_lo(k-1,i  ,j  ) )
          call check( __line__, phi_lo(k+1,i  ,j  ) )
          call check( __line__, phi_lo(k  ,i-1,j  ) )
          call check( __line__, phi_lo(k  ,i+1,j  ) )
          call check( __line__, phi_lo(k  ,i  ,j+1) )
          call check( __line__, phi_lo(k  ,i  ,j-1) )
#endif
          qmax = max( phi_in(k  ,i  ,j  ), &
                      phi_in(k+1,i  ,j  ), &
                      phi_in(k-1,i  ,j  ), &
                      phi_in(k  ,i+1,j  ), &
                      phi_in(k  ,i-1,j  ), &
                      phi_in(k  ,i  ,j+1), &
                      phi_in(k  ,i  ,j-1), &
                      phi_lo(k  ,i  ,j  ), &
                      phi_lo(k+1,i  ,j  ), &
                      phi_lo(k-1,i  ,j  ), &
                      phi_lo(k  ,i+1,j  ), &
                      phi_lo(k  ,i-1,j  ), &
                      phi_lo(k  ,i  ,j+1), &
                      phi_lo(k  ,i  ,j-1) )
          qmin = min( phi_in(k  ,i  ,j  ), &
                      phi_in(k+1,i  ,j  ), &
                      phi_in(k-1,i  ,j  ), &
                      phi_in(k  ,i-1,j  ), &
                      phi_in(k  ,i+1,j  ), &
                      phi_in(k  ,i  ,j+1), &
                      phi_in(k  ,i  ,j-1), &
                      phi_lo(k  ,i  ,j  ), &
                      phi_lo(k+1,i  ,j  ), &
                      phi_lo(k-1,i  ,j  ), &
                      phi_lo(k  ,i-1,j  ), &
                      phi_lo(k  ,i+1,j  ), &
                      phi_lo(k  ,i  ,j+1), &
                      phi_lo(k  ,i  ,j-1) )
          qjpls(k,i,j) = ( qmax - phi_lo(k,i,j) ) * dens(k,i,j)
          qjmns(k,i,j) = ( phi_lo(k,i,j) - qmin ) * dens(k,i,j)
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif
       !$omp parallel do private(i,j,qmax,qmin) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
#ifdef DEBUG
          call check( __line__, phi_in(ks  ,i  ,j  ) )
          call check( __line__, phi_in(ks+1,i  ,j  ) )
          call check( __line__, phi_in(ks  ,i-1,j  ) )
          call check( __line__, phi_in(ks  ,i+1,j  ) )
          call check( __line__, phi_in(ks  ,i  ,j+1) )
          call check( __line__, phi_in(ks  ,i  ,j-1) )
          call check( __line__, phi_lo(ks  ,i  ,j  ) )
          call check( __line__, phi_lo(ks+1,i  ,j  ) )
          call check( __line__, phi_lo(ks  ,i-1,j  ) )
          call check( __line__, phi_lo(ks  ,i+1,j  ) )
          call check( __line__, phi_lo(ks  ,i  ,j+1) )
          call check( __line__, phi_lo(ks  ,i  ,j-1) )
          call check( __line__, phi_in(ke  ,i  ,j  ) )
          call check( __line__, phi_in(ke-1,i  ,j  ) )
          call check( __line__, phi_in(ke  ,i-1,j  ) )
          call check( __line__, phi_in(ke  ,i+1,j  ) )
          call check( __line__, phi_in(ke  ,i  ,j+1) )
          call check( __line__, phi_in(ke  ,i  ,j-1) )
          call check( __line__, phi_lo(ke  ,i  ,j  ) )
          call check( __line__, phi_lo(ke-1,i  ,j  ) )
          call check( __line__, phi_lo(ke  ,i-1,j  ) )
          call check( __line__, phi_lo(ke  ,i+1,j  ) )
          call check( __line__, phi_lo(ke  ,i  ,j+1) )
          call check( __line__, phi_lo(ke  ,i  ,j-1) )
#endif
          qmax = max( phi_in(ks  ,i  ,j  ), &
                      phi_in(ks+1,i  ,j  ), &
                      phi_in(ks  ,i+1,j  ), &
                      phi_in(ks  ,i-1,j  ), &
                      phi_in(ks  ,i  ,j+1), &
                      phi_in(ks  ,i  ,j-1), &
                      phi_lo(ks  ,i  ,j  ), &
                      phi_lo(ks+1,i  ,j  ), &
                      phi_lo(ks  ,i+1,j  ), &
                      phi_lo(ks  ,i-1,j  ), &
                      phi_lo(ks  ,i  ,j+1), &
                      phi_lo(ks  ,i  ,j-1) )
          qmin = min( phi_in(ks  ,i  ,j  ), &
                      phi_in(ks+1,i  ,j  ), &
                      phi_in(ks  ,i+1,j  ), &
                      phi_in(ks  ,i-1,j  ), &
                      phi_in(ks  ,i  ,j+1), &
                      phi_in(ks  ,i  ,j-1), &
                      phi_lo(ks  ,i  ,j  ), &
                      phi_lo(ks+1,i  ,j  ), &
                      phi_lo(ks  ,i+1,j  ), &
                      phi_lo(ks  ,i-1,j  ), &
                      phi_lo(ks  ,i  ,j+1), &
                      phi_lo(ks  ,i  ,j-1) )
          qjmns(ks,i,j) = ( phi_lo(ks,i,j) - qmin ) * dens(ks,i,j)
          qjpls(ks,i,j) = ( qmax - phi_lo(ks,i,j) ) * dens(ks,i,j)

          qmax = max( phi_in(ke  ,i  ,j  ), &
                      phi_in(ke-1,i  ,j  ), &
                      phi_in(ke  ,i+1,j  ), &
                      phi_in(ke  ,i-1,j  ), &
                      phi_in(ke  ,i  ,j+1), &
                      phi_in(ke  ,i  ,j-1), &
                      phi_lo(ke  ,i  ,j  ), &
                      phi_lo(ke-1,i  ,j  ), &
                      phi_lo(ke  ,i+1,j  ), &
                      phi_lo(ke  ,i-1,j  ), &
                      phi_lo(ke  ,i  ,j+1), &
                      phi_lo(ke  ,i  ,j-1) )
          qmin = min( phi_in(ke  ,i  ,j  ), &
                      phi_in(ke-1,i  ,j  ), &
                      phi_in(ke  ,i-1,j  ), &
                      phi_in(ke  ,i+1,j  ), &
                      phi_in(ke  ,i  ,j+1), &
                      phi_in(ke  ,i  ,j-1), &
                      phi_lo(ke  ,i  ,j  ), &
                      phi_lo(ke-1,i  ,j  ), &
                      phi_lo(ke  ,i-1,j  ), &
                      phi_lo(ke  ,i+1,j  ), &
                      phi_lo(ke  ,i  ,j+1), &
                      phi_lo(ke  ,i  ,j-1) )
          qjpls(ke,i,j) = ( qmax - phi_lo(ke,i,j) ) * dens(ke,i,j)
          qjmns(ke,i,j) = ( phi_lo(ke,i,j) - qmin ) * dens(ke,i,j)
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif
       end if

       !--- incoming flux limitation factor [0-1]
       !$omp parallel do private(i,j,k,zerosw) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, pjpls(k,i,j) )
          call check( __line__, qjpls(k,i,j) )
#endif
          ! if pjpls == 0, zerosw = 1 and rjpls = 0
          zerosw = 0.5_rp - sign( 0.5_rp, pjpls(k,i,j)-epsilon )
          rjpls(k,i,j) = min( 1.0_rp, qjpls(k,i,j) * ( 1.0_rp-zerosw ) / ( pjpls(k,i,j)-zerosw ) )
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

       !--- outgoing flux limitation factor [0-1]
       !$omp parallel do private(i,j,k,zerosw) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, pjmns(k,i,j) )
          call check( __line__, qjmns(k,i,j) )
#endif
          ! if pjmns == 0, zerosw = 1 and rjmns = 0
          zerosw = 0.5_rp - sign( 0.5_rp, pjmns(k,i,j)-epsilon )
          rjmns(k,i,j) = min( 1.0_rp, qjmns(k,i,j) * ( 1.0_rp-zerosw ) / ( pjmns(k,i,j)-zerosw ) )
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

    enddo
    enddo

    call comm_vars8( rjpls(:,:,:), 1 )
    call comm_vars8( rjmns(:,:,:), 2 )
    call comm_wait ( rjpls(:,:,:), 1 )
    call comm_wait ( rjmns(:,:,:), 2 )

    do jjs = js, je, jblock
    jje = jjs+jblock-1
    do iis = is, ie, iblock
    iie = iis+iblock-1

       !--- update high order flux with antidiffusive flux
       !$omp parallel do private(i,j,k,dirsw) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
       do k = ks , ke-1
#ifdef DEBUG
          call check( __line__, qflx_anti(k,i,j,zdir) )
          call check( __line__, rjpls(k  ,i,j) )
          call check( __line__, rjpls(k+1,i,j) )
          call check( __line__, rjmns(k  ,i,j) )
          call check( __line__, rjmns(k+1,i,j) )
#endif
          ! if qflx_anti > 0, dirsw = 1
          dirsw = 0.5_rp + sign( 0.5_rp, qflx_anti(k,i,j,zdir) )
          qflx_anti(k,i,j,zdir) = qflx_anti(k,i,j,zdir) &
                 * ( 1.0_rp &
                   - min( rjpls(k+1,i,j),rjmns(k  ,i,j) ) * (          dirsw ) &
                   - min( rjpls(k  ,i,j),rjmns(k+1,i,j) ) * ( 1.0_rp - dirsw ) )
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif
       !$omp parallel do private(i,j) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = iis, iie
#ifdef DEBUG
          call check( __line__, qflx_anti(ke,i,j,zdir) )
          call check( __line__, rjpls(ke  ,i,j) )
          call check( __line__, rjmns(ke  ,i,j) )
#endif
          qflx_anti(ks-1,i,j,zdir) = 0.0_rp ! bottom boundary
          qflx_anti(ke  ,i,j,zdir) = 0.0_rp ! top    boundary
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

       if ( iis == is ) then
          ijs = iis-1
       else
          ijs = iis
       end if

       !$omp parallel do private(i,j,k,dirsw) OMP_SCHEDULE_ collapse(2)
       do j = jjs, jje
       do i = ijs, iie
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, qflx_anti(k,i,j,xdir) )
          call check( __line__, rjpls(k,i  ,j) )
          call check( __line__, rjpls(k,i+1,j) )
          call check( __line__, rjmns(k,i  ,j) )
          call check( __line__, rjmns(k,i+1,j) )
#endif
          ! if qflx_anti > 0, dirsw = 1
          dirsw = 0.5_rp + sign( 0.5_rp, qflx_anti(k,i,j,xdir) )
          qflx_anti(k,i,j,xdir) = qflx_anti(k,i,j,xdir) &
                 * ( 1.0_rp &
                   - min( rjpls(k,i+1,j),rjmns(k,i  ,j) ) * (          dirsw ) &
                   - min( rjpls(k,i  ,j),rjmns(k,i+1,j) ) * ( 1.0_rp - dirsw ) )
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

       if ( jjs == js ) then
          ijs = jjs-1
       else
          ijs = jjs
       end if
       !$omp parallel do private(i,j,k,dirsw) OMP_SCHEDULE_ collapse(2)
       do j = ijs, jje
       do i = iis, iie
       do k = ks, ke
#ifdef DEBUG
          call check( __line__, qflx_anti(k,i,j,ydir) )
          call check( __line__, rjpls(k,i,j+1) )
          call check( __line__, rjpls(k,i,j  ) )
          call check( __line__, rjmns(k,i,j  ) )
          call check( __line__, rjmns(k,i,j+1) )
#endif
          ! if qflx_anti > 0, dirsw = 1
          dirsw = 0.5_rp + sign( 0.5_rp, qflx_anti(k,i,j,ydir) )
          qflx_anti(k,i,j,ydir) = qflx_anti(k,i,j,ydir) &
                 * ( 1.0_rp &
                   - min( rjpls(k,i,j+1),rjmns(k,i,j  ) ) * (          dirsw ) &
                   - min( rjpls(k,i,j  ),rjmns(k,i,j+1) ) * ( 1.0_rp - dirsw ) )
       enddo
       enddo
       enddo
#ifdef DEBUG
       k = iundef; i = iundef; j = iundef
#endif

    enddo
    enddo

    return

Here is the call graph for this function:

Here is the caller graph for this function: