480 lines
14 KiB
Fortran
480 lines
14 KiB
Fortran
MODULE Compact
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IMPLICIT NONE
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REAL(KIND=8), DIMENSION(:), ALLOCATABLE :: lxf,lxs,wxf,wxs, &
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lyf,lys,wyf,wys, &
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lzf,lzs,wzf,wzs
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INTEGER :: nxc,nyc,nzc
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REAL(KIND=8), PARAMETER :: ezero = 1.0e-14
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CONTAINS
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SUBROUTINE ludcmp(nx,ny,nz,xp,yp,zp)
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INTEGER, INTENT(IN) :: nx,ny,nz
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INTEGER, INTENT(IN) :: xp,yp,zp
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INTEGER :: ierr
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nxc=nx
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nyc=ny
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nzc=nz
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CALL ludcmp_allocate(nx,ny,nz,xp,yp,zp)
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CALL ludcmp_calculate(nx,ny,nz,xp,yp,zp)
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END SUBROUTINE ludcmp
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SUBROUTINE ludcmp_allocate(nx,ny,nz,xp,yp,zp)
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INTEGER, INTENT(IN) :: nx,ny,nz
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INTEGER, INTENT(IN) :: xp,yp,zp
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INTEGER :: ierr
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nxc=nx
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nyc=ny
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nzc=nz
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! IF(nyc /= nzc) PRINT*,'ny should be equal nz'
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! xp, yp, zp = 0 : periodic
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ALLOCATE(lxf(nxc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ALLOCATE(lxs(nxc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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IF(xp.eq.0) THEN
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ALLOCATE(wxf(nxc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ALLOCATE(wxs(nxc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ENDIF
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ALLOCATE(lyf(nyc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ALLOCATE(lys(nyc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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IF(yp.eq.0) THEN
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ALLOCATE(wyf(nyc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ALLOCATE(wys(nyc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ENDIF
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ALLOCATE(lzf(nzc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ALLOCATE(lzs(nzc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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IF(zp.eq.0) THEN
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ALLOCATE(wzf(nzc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ALLOCATE(wzs(nzc),STAT=ierr)
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IF(ierr /= 0) PRINT*, 'work array for lud allocation failed'
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ENDIF
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END SUBROUTINE ludcmp_allocate
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SUBROUTINE ludcmp_deallocate(xp,yp,zp)
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INTEGER, INTENT(IN) :: xp,yp,zp
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! IF(nyc /= nzc) PRINT*,'ny should be equal nz'
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! xp, yp, zp = 0 : periodic
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DEALLOCATE(lxf)
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DEALLOCATE(lxs)
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IF(xp.eq.0) THEN
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DEALLOCATE(wxf)
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DEALLOCATE(wxs)
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ENDIF
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DEALLOCATE(lyf)
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DEALLOCATE(lys)
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IF(yp.eq.0) THEN
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DEALLOCATE(wyf)
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DEALLOCATE(wys)
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ENDIF
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DEALLOCATE(lzf)
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DEALLOCATE(lzs)
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IF(zp.eq.0) THEN
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DEALLOCATE(wzf)
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DEALLOCATE(wzs)
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ENDIF
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END SUBROUTINE ludcmp_deallocate
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SUBROUTINE ludcmp_testalloc
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IF (.not. ALLOCATED(lxf)) print *, "lxf not allocated"
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IF (.not. ALLOCATED(lxs)) print *, "lxs not allocated"
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IF (.not. ALLOCATED(wxf)) print *, "wxf not allocated"
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IF (.not. ALLOCATED(wxs)) print *, "wxs not allocated"
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IF (.not. ALLOCATED(lyf)) print *, "lyf not allocated"
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IF (.not. ALLOCATED(lys)) print *, "lys not allocated"
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IF (.not. ALLOCATED(wyf)) print *, "wyf not allocated"
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IF (.not. ALLOCATED(wys)) print *, "wys not allocated"
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IF (.not. ALLOCATED(lzf)) print *, "lzf not allocated"
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IF (.not. ALLOCATED(lzs)) print *, "lzs not allocated"
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IF (.not. ALLOCATED(wzf)) print *, "wzf not allocated"
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IF (.not. ALLOCATED(wzs)) print *, "wzs not allocated"
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END SUBROUTINE ludcmp_testalloc
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SUBROUTINE ludcmp_calculate(nx,ny,nz,xp,yp,zp)
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INTEGER, INTENT(IN) :: nx,ny,nz
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INTEGER, INTENT(IN) :: xp,yp,zp
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INTEGER :: ierr
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nxc=nx
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nyc=ny
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nzc=nz
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CALL ludcmp_testalloc
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! IF(nyc /= nzc) PRINT*,'ny should be equal nz'
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! xp, yp, zp = 0 : periodic
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IF(xp.eq.0) THEN
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CALL p_lud(1,nxc)
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ELSE
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CALL nonp_lud(1,nxc)
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ENDIF
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IF(yp.eq.0) THEN
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CALL p_lud(2,nyc)
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ELSE
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call nonp_lud(2,nyc)
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ENDIF
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IF(zp.eq.0) THEN
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CALL p_lud(3,nzc)
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ELSE
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call nonp_lud(3,nzc)
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ENDIF
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END SUBROUTINE ludcmp_calculate
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SUBROUTINE nonp_lud(xyz,xx)
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INTEGER :: i,xyz,xx
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REAL(KIND=8), DIMENSION(xx) :: aa
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aa=3.
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aa(1)=0.5 ; aa(2)=4.
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aa(xx-1)=4. ; aa(xx)=0.5
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! first derivative
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IF (xyz.eq.1) CALL stdlu(aa,xx,lxf) ! x-direction
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IF (xyz.eq.2) CALL stdlu(aa,xx,lyf) ! y-direction
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IF (xyz.eq.3) CALL stdlu(aa,xx,lzf) ! z-direction
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aa=5.5
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aa(1)=2./11. ; aa(2)=10.
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aa(xx-1)=10. ; aa(xx)=2./11.
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! second derivative
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IF (xyz.eq.1) CALL stdlu(aa,xx,lxs) ! x-direction
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IF (xyz.eq.2) CALL stdlu(aa,xx,lys) ! y-direction
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IF (xyz.eq.3) CALL stdlu(aa,xx,lzs) ! z-direction
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END SUBROUTINE nonp_lud
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SUBROUTINE p_lud(xyz,xx)
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INTEGER :: i,xyz,xx
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REAL(KIND=8) :: a
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a=3. ! first derivative
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IF (xyz.eq.1) CALL ptdlu(a,xx,lxf,wxf) ! x-direction
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IF (xyz.eq.2) CALL ptdlu(a,xx,lyf,wyf) ! y-direction
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IF (xyz.eq.3) CALL ptdlu(a,xx,lzf,wzf) ! z-direction
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a=11./2. ! second derivative
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IF (xyz.eq.1) CALL ptdlu(a,xx,lxs,wxs) ! x-direction
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IF (xyz.eq.2) CALL ptdlu(a,xx,lys,wys) ! y-direction
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IF (xyz.eq.3) CALL ptdlu(a,xx,lzs,wzs) ! z-direction
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END SUBROUTINE p_lud
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SUBROUTINE stdlu(a,n,l)
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INTEGER :: n
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REAL(KIND=8) :: a(n),l(n)
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REAL(KIND=8) :: d
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INTEGER :: i
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l(1)=1.0/a(1)
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DO i=2,n
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d=a(i)-l(i-1)
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l(i)=1.0/d
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ENDDO
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END SUBROUTINE stdlu
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SUBROUTINE ptdlu(a,n,l,w)
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INTEGER :: n
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REAL(KIND=8) :: a,l(n),w(n)
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INTEGER :: i
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REAL(KIND=8) :: aa(n),d
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DO i=1,n-1
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aa(i)=a
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ENDDO
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i=n-1
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call stdlu(aa,i,l)
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w(1)=1.0
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DO i=2,n-2
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w(i)=-l(i-1)*w(i-1)
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ENDDO
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w(n-1)=1.0-l(n-2)*w(n-2)
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DO i=1,n-1
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w(i)=w(i)*l(i)
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ENDDO
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d=a
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DO i=1,n-1
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d=d-w(i)*w(i)/l(i)
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ENDDO
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l(n)=1./d
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END SUBROUTINE ptdlu
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SUBROUTINE dfnonp(n,h,x,dx,nd,dir)
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INTEGER,INTENT(IN) :: n,nd,dir
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REAL(KIND=8),INTENT(IN) :: h
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REAL(KIND=8),INTENT(IN),DIMENSION(nd,n) :: x
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REAL(KIND=8),INTENT(OUT),DIMENSION(nd,n) :: dx
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INTEGER :: i,j
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REAL(KIND=8) :: r1,r2,r3,a,b,c,h1,t1,t2,t3,t4
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! print *, "dfnonp received (nd,n)", nd, n
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h1=1./h
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r1=7./3.
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r2=1./12.
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r3=3.
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a=-1.25
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b=1.
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c=0.25
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DO j=1,nd
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dx(j,n-1)=x(j,n)-x(j,n-2)
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dx(j,n)=-(a*x(j,n)+b*x(j,n-1)+c*x(j,n-2))
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dx(j,1)=(a*x(j,1)+b*x(j,2)+c*x(j,3))
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dx(j,2)=x(j,3)-x(j,1)
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IF (x(j,n).eq.x(j,n-1).and.x(j,n-1).eq.x(j,n-2)) dx(j,n)=0.
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IF (x(j,1).eq.x(j,2).and.x(j,2).eq.x(j,3)) dx(j,1)=0.
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dx(j,n-1)=dx(j,n-1)*h1*r3
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dx(j,n)=dx(j,n)*h1
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dx(j,1)=dx(j,1)*h1
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dx(j,2)=dx(j,2)*h1*r3
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ENDDO
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DO i=3,n-2
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DO j=1,nd
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t1=x(j,i+1)-x(j,i-1)
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t2=x(j,i+2)-x(j,i-2)
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dx(j,i)=h1*(r1*t1+r2*t2)
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ENDDO
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ENDDO
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IF (dir.eq.1) CALL tdslv(dx,n,lxf,nd) ! x-direction
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IF (dir.eq.2) CALL tdslv(dx,n,lyf,nd) ! y-direction
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IF (dir.eq.3) CALL tdslv(dx,n,lzf,nd) ! z-direction
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END SUBROUTINE dfnonp
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SUBROUTINE dfp(n,h,x,dx,nd,dir)
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INTEGER,INTENT(IN) :: n,nd,dir
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REAL(KIND=8),INTENT(IN) :: h
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REAL(KIND=8),INTENT(IN),DIMENSION(nd,n) :: x
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REAL(KIND=8),INTENT(OUT),DIMENSION(nd,n) :: dx
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INTEGER :: i,j
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REAL(KIND=8) :: r1,r2,h1
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! print *, "dfnonp received (nd,n)", nd, n
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h1=1./h
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r1=7./3.
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r2=1./12.
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DO j=1,nd
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dx(j,n-1)=(r1*(x(j,n)-x(j,n-2))+r2*(x(j,1)-x(j,n-3)))
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dx(j,n)=(r1*(x(j,1)-x(j,n-1))+r2*(x(j,2)-x(j,n-2)))
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dx(j,1)=(r1*(x(j,2)-x(j,n))+r2*(x(j,3)-x(j,n-1)))
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dx(j,2)=(r1*(x(j,3)-x(j,1))+r2*(x(j,4)-x(j,n)))
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dx(j,n-1)=dx(j,n-1)*h1
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dx(j,n)=dx(j,n)*h1
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dx(j,1)=dx(j,1)*h1
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dx(j,2)=dx(j,2)*h1
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ENDDO
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DO i=3,n-2
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DO j=1,nd
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dx(j,i)=(r1*(x(j,i+1)-x(j,i-1))+r2*(x(j,i+2)-x(j,i-2)))
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dx(j,i)=dx(j,i)*h1
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ENDDO
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ENDDO
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IF (dir.eq.1) CALL ptdslv(dx,n,lxf,wxf,nd) ! x-direction
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IF (dir.eq.2) CALL ptdslv(dx,n,lyf,wyf,nd) ! y-direction
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IF (dir.eq.3) CALL ptdslv(dx,n,lzf,wzf,nd) ! z-direction
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END SUBROUTINE dfp
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SUBROUTINE ptdslv(r,n,l,w,nd)
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INTEGER,INTENT(IN) :: n,nd
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REAL(KIND=8),INTENT(INOUT),DIMENSION(nd,n) :: r
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REAL(KIND=8),INTENT(IN),DIMENSION(:) :: l,w
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INTEGER i,j
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REAL(KIND=8), DIMENSION(nd) :: sum
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DO j=1,nd
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sum(j)=w(1)*r(j,1)
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r(j,1)=r(j,1)*l(1)
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ENDDO
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DO i=2,n-1
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DO j=1,nd
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r(j,i)=r(j,i)-r(j,i-1)
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sum(j)=sum(j)+w(i)*r(j,i)
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r(j,i)=r(j,i)*l(i)
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ENDDO
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ENDDO
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DO j=1,nd
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r(j,n)=l(n)*(r(j,n)-sum(j))
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r(j,n-1)=r(j,n-1)-w(n-1)*r(j,n)
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ENDDO
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DO i=n-2,1,-1
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DO j=1,nd
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r(j,i)=r(j,i)-l(i)*r(j,i+1)-w(i)*r(j,n)
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ENDDO
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ENDDO
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END SUBROUTINE ptdslv
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SUBROUTINE d2fp(n,h,x,dx,nd,dir)
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INTEGER,INTENT(IN) :: n,nd,dir
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REAL(KIND=8),INTENT(IN) :: h
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REAL(KIND=8),INTENT(IN),DIMENSION(nd,n) :: x
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REAL(KIND=8),INTENT(OUT),DIMENSION(nd,n) :: dx
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INTEGER :: i,j
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REAL(KIND=8) :: h2,r1,r2,t1,t2
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h2=1./(h*h)
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r1=6.
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r2=3./8.
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DO j=1,nd
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t1 = (x(j,n)-2.*x(j,n-1)+x(j,n-2))
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t2 = (x(j,1)-2.*x(j,n-1)+x(j,n-3))
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IF (x(j,n).eq.x(j,n-1).and.x(j,n-1).eq.x(j,n-2)) t1=0.
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IF (x(j,1).eq.x(j,n-1).and.x(j,n-1).eq.x(j,n-3)) t2=0.
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dx(j,n-1)=(r1*t1+r2*t2)
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t1 = (x(j,1)-2.*x(j,n)+x(j,n-1))
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t2 = (x(j,2)-2.*x(j,n)+x(j,n-2))
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IF (x(j,1).eq.x(j,n).and.x(j,n).eq.x(j,n-1)) t1=0.
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IF (x(j,2).eq.x(j,n).and.x(j,n).eq.x(j,n-2)) t2=0.
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! dx(j,n)=(r1*(x(j,1)-2.*x(j,n)+x(j,n-1)) &
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! +r2*(x(j,2)-2.*x(j,n)+x(j,n-2)))
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dx(j,n)=(r1*t1+r2*t2)
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t1 = (x(j,2)-2.*x(j,1)+x(j,n))
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t2 = (x(j,3)-2.*x(j,1)+x(j,n-1))
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IF (x(j,2).eq.x(j,1).and.x(j,1).eq.x(j,n)) t1=0.
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IF (x(j,3).eq.x(j,1).and.x(j,1).eq.x(j,n-1)) t2=0.
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! dx(j,1)=(r1*(x(j,2)-2.*x(j,1)+x(j,n)) &
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! +r2*(x(j,3)-2.*x(j,1)+x(j,n-1)))
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dx(j,1)=(r1*t1+r2*t2)
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t1 = (x(j,3)-2.*x(j,2)+x(j,1))
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t2 = (x(j,4)-2.*x(j,2)+x(j,n))
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IF (x(j,3).eq.x(j,2).and.x(j,2).eq.x(j,1)) t1=0.
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IF (x(j,4).eq.x(j,2).and.x(j,2).eq.x(j,n)) t2=0.
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! dx(j,2)=(r1*(x(j,3)-2.*x(j,2)+x(j,1)) &
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! +r2*(x(j,4)-2.*x(j,2)+x(j,n)))
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dx(j,2)=(r1*t1+r2*t2)
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dx(j,n-1)=dx(j,n-1)*h2
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dx(j,n)=dx(j,n)*h2
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dx(j,1)=dx(j,1)*h2
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dx(j,2)=dx(j,2)*h2
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ENDDO
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DO i=3,n-2
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DO j=1,nd
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t1 = (x(j,i+1)-2.*x(j,i)+x(j,i-1))
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t2 = (x(j,i+2)-2.*x(j,i)+x(j,i-2))
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IF (x(j,i+1).eq.x(j,i).and.x(j,i).eq.x(j,i-1)) t1=0.
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IF (x(j,i+2).eq.x(j,i).and.x(j,i).eq.x(j,i-2)) t2=0.
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! dx(j,i)=(r1*(x(j,i+1)-2.*x(j,i)+x(j,i-1)) &
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! +r2*(x(j,i+2)-2.*x(j,i)+x(j,i-2)))
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dx(j,i)=(r1*t1+r2*t2)
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dx(j,i)=dx(j,i)*h2
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ENDDO
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ENDDO
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IF (dir.eq.1) CALL ptdslv(dx,n,lxs,wxs,nd) ! x-direction
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IF (dir.eq.2) CALL ptdslv(dx,n,lys,wys,nd) ! y-direction
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IF (dir.eq.3) CALL ptdslv(dx,n,lzs,wzs,nd) ! z-direction
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END SUBROUTINE d2fp
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SUBROUTINE tdslv(r,n,l,nd)
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INTEGER,INTENT(IN) :: n,nd
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REAL(KIND=8),INTENT(INOUT),DIMENSION(nd,n) :: r
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REAL(KIND=8),INTENT(IN),DIMENSION(:) :: l
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INTEGER i,j
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REAL(KIND=8) t1
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DO j=1,nd
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r(j,1)=r(j,1)*l(1)
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ENDDO
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DO i=2,n
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DO j=1,nd
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t1=r(j,i)-r(j,i-1)
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r(j,i)=l(i)*t1
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ENDDO
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ENDDO
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DO i=n-1,1,-1
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DO j=1,nd
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r(j,i)=r(j,i)-l(i)*r(j,i+1)
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ENDDO
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ENDDO
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END SUBROUTINE tdslv
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SUBROUTINE d2fnonp(n,h,x,dx,nd,dir)
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INTEGER,INTENT(IN) :: n,nd,dir
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REAL(KIND=8),INTENT(IN) :: h
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REAL(KIND=8),INTENT(IN),DIMENSION(nd,n) :: x
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REAL(KIND=8),INTENT(OUT),DIMENSION(nd,n) :: dx
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INTEGER :: i,j
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REAL(KIND=8) :: h2,r1,r2,r3,a,b,c,e,t1,t2
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h2=1./(h*h)
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r1=6.
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r2=3./8.
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r3=12.
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a=13./11.
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b=-27./11.
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c=15./11.
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e=-1./11.
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DO j=1,nd
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dx(j,1)=(a*x(j,1)+b*x(j,2)+c*x(j,3)+e*x(j,4))
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dx(j,2)=(x(j,3)-2.*x(j,2)+x(j,1))
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dx(j,n-1)=(x(j,n)-2.*x(j,n-1)+x(j,n-2))
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dx(j,n)=(a*x(j,n)+b*x(j,n-1)+c*x(j,n-2)+e*x(j,n-3))
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IF (x(j,1).eq.x(j,2).and.x(j,2).eq.x(j,3).and.x(j,3).eq.x(j,4)) dx(j,1)=0.
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IF (x(j,3).eq.x(j,2).and.x(j,2).eq.x(j,1)) dx(j,2)=0.
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IF (x(j,n).eq.x(j,n-1).and.x(j,n-1).eq.x(j,n-2).and.x(j,n-2).eq.x(j,n-3)) dx(j,n)=0.
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IF (x(j,n).eq.x(j,n-1).and.x(j,n-1).eq.x(j,n-2)) dx(j,n-1)=0.
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dx(j,1)=dx(j,1)*h2
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dx(j,2)=dx(j,2)*h2*r3
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dx(j,n-1)=dx(j,n-1)*h2*r3
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dx(j,n)=dx(j,n)*h2
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ENDDO
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DO i=3,n-2
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DO j=1,nd
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t1 = (x(j,i+1)-2.*x(j,i)+x(j,i-1))
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t2 = (x(j,i+2)-2.*x(j,i)+x(j,i-2))
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IF (x(j,i+1).eq.x(j,i).and.x(j,i).eq.x(j,i-1)) t1=0.
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IF (x(j,i+2).eq.x(j,i).and.x(j,i).eq.x(j,i-2)) t2=0.
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! dx(j,i)=(r1*(x(j,i+1)-2.*x(j,i)+x(j,i-1)) &
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! +r2*(x(j,i+2)-2.*x(j,i)+x(j,i-2)))
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dx(j,i)=(r1*t1+r2*t2)
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dx(j,i)=dx(j,i)*h2
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ENDDO
|
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ENDDO
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IF (dir.eq.1) CALL tdslv(dx,n,lxs,nd) ! x-direction
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IF (dir.eq.2) CALL tdslv(dx,n,lys,nd) ! y-direction
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IF (dir.eq.3) CALL tdslv(dx,n,lzs,nd) ! z-direction
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END SUBROUTINE d2fnonp
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END MODULE Compact
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