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|
/*@@
@file GRHydro_Source.F90
@date Sat Jan 26 02:03:56 2002
@author Ian Hawke
@desc
The geometric source terms for the matter evolution
@enddesc
@@*/
! Second order f.d.
#define DIFF_X_2(q) 0.5d0 * (q(i+1,j,k) - q(i-1,j,k)) * idx
#define DIFF_Y_2(q) 0.5d0 * (q(i,j+1,k) - q(i,j-1,k)) * idy
#define DIFF_Z_2(q) 0.5d0 * (q(i,j,k+1) - q(i,j,k-1)) * idz
! Fourth order f.d.
#define DIFF_X_4(q) (-q(i+2,j,k) + 8.d0 * q(i+1,j,k) - 8.d0 * q(i-1,j,k) + \
q(i-2,j,k)) / 12.d0 * idx
#define DIFF_Y_4(q) (-q(i,j+2,k) + 8.d0 * q(i,j+1,k) - 8.d0 * q(i,j-1,k) + \
q(i,j-2,k)) / 12.d0 * idy
#define DIFF_Z_4(q) (-q(i,j,k+2) + 8.d0 * q(i,j,k+1) - 8.d0 * q(i,j,k-1) + \
q(i,j,k-2)) / 12.d0 * idz
#include "cctk.h"
#include "cctk_Parameters.h"
#include "cctk_Arguments.h"
#include "GRHydro_Macros.h"
#define velx(i,j,k) vel(i,j,k,1)
#define vely(i,j,k) vel(i,j,k,2)
#define velz(i,j,k) vel(i,j,k,3)
/*@@
@routine SourceTerms
@date Sat Jan 26 02:04:21 2002
@author Ian Hawke
@desc
Calculate the geometric source terms and add to the update GFs
@enddesc
@calls
@calledby
@history
Minor alterations of routine from GR3D.
@endhistory
@@*/
subroutine SourceTerms(CCTK_ARGUMENTS)
implicit none
DECLARE_CCTK_ARGUMENTS
DECLARE_CCTK_PARAMETERS
CCTK_INT :: i, j, k, nx, ny, nz
CCTK_REAL :: one, two, half
CCTK_REAL :: t00, t0x, t0y, t0z, txx, txy, txz, tyy, tyz, tzz
CCTK_REAL :: sqrtdet, det, uxx, uxy, uxz, uyy, uyz, uzz, rhoenthalpyW2
CCTK_REAL :: shiftx, shifty, shiftz, velxshift, velyshift, velzshift
CCTK_REAL :: vlowx, vlowy, vlowz
CCTK_REAL :: dx_betax, dx_betay, dx_betaz, dy_betax, dy_betay,&
dy_betaz, dz_betax, dz_betay, dz_betaz
CCTK_REAL :: dx_alp, dy_alp, dz_alp
CCTK_REAL :: tau_source, sx_source, sy_source, sz_source
CCTK_REAL :: localgxx,localgxy,localgxz,localgyy,localgyz,localgzz
CCTK_REAL :: dx_gxx, dx_gxy, dx_gxz, dx_gyy, dx_gyz, dx_gzz
CCTK_REAL :: dy_gxx, dy_gxy, dy_gxz, dy_gyy, dy_gyz, dy_gzz
CCTK_REAL :: dz_gxx, dz_gxy, dz_gxz, dz_gyy, dz_gyz, dz_gzz
CCTK_REAL :: dx, dy, dz, idx, idy, idz
CCTK_REAL :: psi4pt, dx_psi4, dy_psi4, dz_psi4
CCTK_REAL :: shiftshiftk, shiftkx, shiftky, shiftkz
CCTK_REAL :: sumTK
CCTK_REAL :: halfshiftdgx, halfshiftdgy, halfshiftdgz
CCTK_REAL :: halfTdgx, halfTdgy, halfTdgz
CCTK_REAL :: invalp, invalp2
logical, allocatable, dimension (:,:,:) :: force_spatial_second_order
one = 1.0d0
two = 2.0d0
half = 0.5d0
nx = cctk_lsh(1)
ny = cctk_lsh(2)
nz = cctk_lsh(3)
dx = CCTK_DELTA_SPACE(1)
dy = CCTK_DELTA_SPACE(2)
dz = CCTK_DELTA_SPACE(3)
idx = 1.d0/dx
idy = 1.d0/dy
idz = 1.d0/dz
!!$ Initialize the update terms to be zero.
!!$ This will guarantee that no garbage in the boundaries is updated.
densrhs = 0.d0
srhs = 0.d0
taurhs = 0.d0
if (evolve_tracer .ne. 0) then
cons_tracerrhs = 0.0d0
end if
if (evolve_Y_e .ne. 0) then
y_e_con_rhs = 0.0d0
endif
!!$ Set up the array for checking the order. We switch to second order
!!$ differencing at boundaries and near excision regions.
!!$ Copied straight from BSSN.
allocate (force_spatial_second_order(nx,ny,nz))
force_spatial_second_order = .FALSE.
if (spatial_order > 2) then
!$OMP PARALLEL DO PRIVATE(i, j)
do k = 1 + GRHydro_stencil, nz - GRHydro_stencil
do j = 1 + GRHydro_stencil, ny - GRHydro_stencil
do i = 1 + GRHydro_stencil, nx - GRHydro_stencil
if ((i < 3).or.(i > cctk_lsh(1) - 2).or. &
(j < 3).or.(j > cctk_lsh(2) - 2).or. &
(k < 3).or.(k > cctk_lsh(3) - 2) ) then
force_spatial_second_order(i,j,k) = .TRUE.
else if ( use_mask > 0 ) then
if (minval(emask(i-2:i+2,j-2:j+2,k-2:k+2)) < 0.75d0) then
force_spatial_second_order(i,j,k) = .TRUE.
end if
end if
end do
end do
end do
!$OMP END PARALLEL DO
end if
!$OMP PARALLEL DO PRIVATE(i, j, local_spatial_order,&
!$OMP localgxx,localgxy,localgxz,localgyy,localgyz,localgzz,&
!$OMP psi4pt,det,sqrtdet,rhoenthalpyW2,shiftx,shifty,shiftz,&
!$OMP dx_betax,dx_betay,dx_betaz,dy_betax,dy_betay,dy_betaz,&
!$OMP dz_betax,dz_betay,dz_betaz,velxshift,velyshift,velzshift,&
!$OMP vlowx,vlowy,vlowz,t00,t0x,t0y,t0z,txx,txy,txz,tyy,tyz,tzz,&
!$OMP dx_alp,dy_alp,dz_alp,tau_source,sx_source,sy_source,sz_source,&
!$OMP uxx, uxy, uxz, uyy, uyz, uzz,&
!$OMP dx_gxx, dx_gxy, dx_gxz, dx_gyy, dx_gyz, dx_gzz,&
!$OMP dy_gxx, dy_gxy, dy_gxz, dy_gyy, dy_gyz, dy_gzz,&
!$OMP dz_gxx, dz_gxy, dz_gxz, dz_gyy, dz_gyz, dz_gzz,&
!$OMP dx_psi4,dy_psi4,dz_psi4,shiftshiftk,shiftkx,shiftky,shiftkz,&
!$OMP sumTK,halfshiftdgx,halfshiftdgy,halfshiftdgz,&
!$OMP halfTdgx,halfTdgy,halfTdgz,invalp,invalp2)
do k=1 + GRHydro_stencil,nz - GRHydro_stencil
do j=1 + GRHydro_stencil,ny - GRHydro_stencil
do i=1 + GRHydro_stencil,nx - GRHydro_stencil
local_spatial_order = spatial_order
if (force_spatial_second_order(i,j,k)) then
local_spatial_order = 2
end if
!!$ Set the metric terms.
localgxx = gxx(i,j,k)
localgxy = gxy(i,j,k)
localgxz = gxz(i,j,k)
localgyy = gyy(i,j,k)
localgyz = gyz(i,j,k)
localgzz = gzz(i,j,k)
det = SPATIAL_DETERMINANT(localgxx, localgxy, localgxz,\
localgyy, localgyz, localgzz)
sqrtdet = sqrt(det)
call UpperMetric(uxx, uxy, uxz, uyy, uyz, uzz, det, localgxx,&
localgxy, localgxz, localgyy, localgyz, localgzz)
!!$ All the matter variables (except velocity) always appear
!!$ together in this form
rhoenthalpyW2 = (rho(i,j,k)*(one + eps(i,j,k)) + press(i,j,k))*&
w_lorentz(i,j,k)**2
if (shift_state .ne. 0) then
shiftx = betax(i,j,k)
shifty = betay(i,j,k)
shiftz = betaz(i,j,k)
if (local_spatial_order .eq. 2) then
dx_betax = DIFF_X_2(betax)
dx_betay = DIFF_X_2(betay)
dx_betaz = DIFF_X_2(betaz)
dy_betax = DIFF_Y_2(betax)
dy_betay = DIFF_Y_2(betay)
dy_betaz = DIFF_Y_2(betaz)
dz_betax = DIFF_Z_2(betax)
dz_betay = DIFF_Z_2(betay)
dz_betaz = DIFF_Z_2(betaz)
else
dx_betax = DIFF_X_4(betax)
dx_betay = DIFF_X_4(betay)
dx_betaz = DIFF_X_4(betaz)
dy_betax = DIFF_Y_4(betax)
dy_betay = DIFF_Y_4(betay)
dy_betaz = DIFF_Y_4(betaz)
dz_betax = DIFF_Z_4(betax)
dz_betay = DIFF_Z_4(betay)
dz_betaz = DIFF_Z_4(betaz)
end if
else
shiftx = 0.0d0
shifty = 0.0d0
shiftz = 0.0d0
dx_betax = 0.0d0
dx_betay = 0.0d0
dx_betaz = 0.0d0
dy_betax = 0.0d0
dy_betay = 0.0d0
dy_betaz = 0.0d0
dz_betax = 0.0d0
dz_betay = 0.0d0
dz_betaz = 0.0d0
endif
invalp = 1.0d0 / alp(i,j,k)
invalp2 = invalp**2
velxshift = velx(i,j,k) - shiftx*invalp
velyshift = vely(i,j,k) - shifty*invalp
velzshift = velz(i,j,k) - shiftz*invalp
vlowx = velx(i,j,k)*localgxx + vely(i,j,k)*localgxy +&
velz(i,j,k)*localgxz
vlowy = velx(i,j,k)*localgxy + vely(i,j,k)*localgyy +&
velz(i,j,k)*localgyz
vlowz = velx(i,j,k)*localgxz + vely(i,j,k)*localgyz +&
velz(i,j,k)*localgzz
!!$ For a change, these are T^{ij}
t00 = (rhoenthalpyW2 - press(i,j,k))*invalp2
t0x = rhoenthalpyW2*velxshift/alp(i,j,k) +&
press(i,j,k)*shiftx*invalp2
t0y = rhoenthalpyW2*velyshift/alp(i,j,k) +&
press(i,j,k)*shifty*invalp2
t0z = rhoenthalpyW2*velzshift/alp(i,j,k) +&
press(i,j,k)*shiftz*invalp2
txx = rhoenthalpyW2*velxshift*velxshift +&
press(i,j,k)*(uxx - shiftx*shiftx*invalp2)
txy = rhoenthalpyW2*velxshift*velyshift +&
press(i,j,k)*(uxy - shiftx*shifty*invalp2)
txz = rhoenthalpyW2*velxshift*velzshift +&
press(i,j,k)*(uxz - shiftx*shiftz*invalp2)
tyy = rhoenthalpyW2*velyshift*velyshift +&
press(i,j,k)*(uyy - shifty*shifty*invalp2)
tyz = rhoenthalpyW2*velyshift*velzshift +&
press(i,j,k)*(uyz - shifty*shiftz*invalp2)
tzz = rhoenthalpyW2*velzshift*velzshift +&
press(i,j,k)*(uzz - shiftz*shiftz*invalp2)
!!$ Derivatives of the lapse, metric and shift
if (local_spatial_order .eq. 2) then
dx_alp = DIFF_X_2(alp)
dy_alp = DIFF_Y_2(alp)
dz_alp = DIFF_Z_2(alp)
else
dx_alp = DIFF_X_4(alp)
dy_alp = DIFF_Y_4(alp)
dz_alp = DIFF_Z_4(alp)
end if
if (local_spatial_order .eq. 2) then
dx_gxx = DIFF_X_2(gxx)
dx_gxy = DIFF_X_2(gxy)
dx_gxz = DIFF_X_2(gxz)
dx_gyy = DIFF_X_2(gyy)
dx_gyz = DIFF_X_2(gyz)
dx_gzz = DIFF_X_2(gzz)
dy_gxx = DIFF_Y_2(gxx)
dy_gxy = DIFF_Y_2(gxy)
dy_gxz = DIFF_Y_2(gxz)
dy_gyy = DIFF_Y_2(gyy)
dy_gyz = DIFF_Y_2(gyz)
dy_gzz = DIFF_Y_2(gzz)
dz_gxx = DIFF_Z_2(gxx)
dz_gxy = DIFF_Z_2(gxy)
dz_gxz = DIFF_Z_2(gxz)
dz_gyy = DIFF_Z_2(gyy)
dz_gyz = DIFF_Z_2(gyz)
dz_gzz = DIFF_Z_2(gzz)
else
dx_gxx = DIFF_X_4(gxx)
dx_gxy = DIFF_X_4(gxy)
dx_gxz = DIFF_X_4(gxz)
dx_gyy = DIFF_X_4(gyy)
dx_gyz = DIFF_X_4(gyz)
dx_gzz = DIFF_X_4(gzz)
dy_gxx = DIFF_Y_4(gxx)
dy_gxy = DIFF_Y_4(gxy)
dy_gxz = DIFF_Y_4(gxz)
dy_gyy = DIFF_Y_4(gyy)
dy_gyz = DIFF_Y_4(gyz)
dy_gzz = DIFF_Y_4(gzz)
dz_gxx = DIFF_Z_4(gxx)
dz_gxy = DIFF_Z_4(gxy)
dz_gxz = DIFF_Z_4(gxz)
dz_gyy = DIFF_Z_4(gyy)
dz_gyz = DIFF_Z_4(gyz)
dz_gzz = DIFF_Z_4(gzz)
end if
!!$ Contract the shift with the extrinsic curvature
shiftshiftk = shiftx*shiftx*kxx(i,j,k) + &
shifty*shifty*kyy(i,j,k) + &
shiftz*shiftz*kzz(i,j,k) + &
two*(shiftx*shifty*kxy(i,j,k) + &
shiftx*shiftz*kxz(i,j,k) + &
shifty*shiftz*kyz(i,j,k))
shiftkx = shiftx*kxx(i,j,k) + shifty*kxy(i,j,k) + shiftz*kxz(i,j,k)
shiftky = shiftx*kxy(i,j,k) + shifty*kyy(i,j,k) + shiftz*kyz(i,j,k)
shiftkz = shiftx*kxz(i,j,k) + shifty*kyz(i,j,k) + shiftz*kzz(i,j,k)
!!$ Contract the matter terms with the extrinsic curvature
sumTK = txx*kxx(i,j,k) + tyy*kyy(i,j,k) + tzz*kzz(i,j,k) &
+ two*(txy*kxy(i,j,k) + txz*kxz(i,j,k) + tyz*kyz(i,j,k))
!!$ Update term for tau
tau_source = t00* &
(shiftshiftk - (shiftx*dx_alp + shifty*dy_alp + shiftz*dz_alp) )&
+ t0x*(-dx_alp + two*shiftkx) &
+ t0y*(-dy_alp + two*shiftky) &
+ t0z*(-dz_alp + two*shiftkz) &
+ sumTK
!!$ The following looks very little like the terms in the
!!$ standard papers. Take a look in the ThornGuide to see why
!!$ it is really the same thing.
!!$ Contract the shift with derivatives of the metric
halfshiftdgx = half*(shiftx*shiftx*dx_gxx + &
shifty*shifty*dx_gyy + shiftz*shiftz*dx_gzz) + &
shiftx*shifty*dx_gxy + shiftx*shiftz*dx_gxz + &
shifty*shiftz*dx_gyz
halfshiftdgy = half*(shiftx*shiftx*dy_gxx + &
shifty*shifty*dy_gyy + shiftz*shiftz*dy_gzz) + &
shiftx*shifty*dy_gxy + shiftx*shiftz*dy_gxz + &
shifty*shiftz*dy_gyz
halfshiftdgz = half*(shiftx*shiftx*dz_gxx + &
shifty*shifty*dz_gyy + shiftz*shiftz*dz_gzz) + &
shiftx*shifty*dz_gxy + shiftx*shiftz*dz_gxz + &
shifty*shiftz*dz_gyz
!!$ Contract the matter with derivatives of the metric
halfTdgx = half*(txx*dx_gxx + tyy*dx_gyy + tzz*dx_gzz) +&
txy*dx_gxy + txz*dx_gxz + tyz*dx_gyz
halfTdgy = half*(txx*dy_gxx + tyy*dy_gyy + tzz*dy_gzz) +&
txy*dy_gxy + txz*dy_gxz + tyz*dy_gyz
halfTdgz = half*(txx*dz_gxx + tyy*dz_gyy + tzz*dz_gzz) +&
txy*dz_gxy + txz*dz_gxz + tyz*dz_gyz
sx_source = t00*&
(halfshiftdgx - alp(i,j,k)*dx_alp) +&
t0x*(shiftx*dx_gxx + shifty*dx_gxy + shiftz*dx_gxz) +&
t0y*(shiftx*dx_gxy + shifty*dx_gyy + shiftz*dx_gyz) +&
t0z*(shiftx*dx_gxz + shifty*dx_gyz + shiftz*dx_gzz) +&
halfTdgx + rhoenthalpyW2*&
(vlowx*dx_betax + vlowy*dx_betay + vlowz*dx_betaz)*&
invalp
sy_source = t00*&
(halfshiftdgy - alp(i,j,k)*dy_alp) +&
t0x*(shiftx*dy_gxx + shifty*dy_gxy + shiftz*dy_gxz) +&
t0y*(shiftx*dy_gxy + shifty*dy_gyy + shiftz*dy_gyz) +&
t0z*(shiftx*dy_gxz + shifty*dy_gyz + shiftz*dy_gzz) +&
halfTdgy + rhoenthalpyW2*&
(vlowx*dy_betax + vlowy*dy_betay + vlowz*dy_betaz)*&
invalp
sz_source = t00*&
(halfshiftdgz - alp(i,j,k)*dz_alp) +&
t0x*(shiftx*dz_gxx + shifty*dz_gxy + shiftz*dz_gxz) +&
t0y*(shiftx*dz_gxy + shifty*dz_gyy + shiftz*dz_gyz) +&
t0z*(shiftx*dz_gxz + shifty*dz_gyz + shiftz*dz_gzz) +&
halfTdgz + rhoenthalpyW2*&
(vlowx*dz_betax + vlowy*dz_betay + vlowz*dz_betaz)*&
invalp
densrhs(i,j,k) = 0.d0
srhs(i,j,k,1) = alp(i,j,k)*sqrtdet*sx_source
srhs(i,j,k,2) = alp(i,j,k)*sqrtdet*sy_source
srhs(i,j,k,3) = alp(i,j,k)*sqrtdet*sz_source
taurhs(i,j,k) = alp(i,j,k)*sqrtdet*tau_source
enddo
enddo
enddo
!$OMP END PARALLEL DO
deallocate(force_spatial_second_order)
end subroutine SourceTerms
|