Subversion Repositories pvinversion.ecmwf

      PROGRAM p2z

c     Calculate the geopotential and add it to the P file

c     Michael Sprenger / Spring 2006

      implicit none

c     ---------------------------------------------------------------

c     Declaration of variables

c     ---------------------------------------------------------------

c     Variables for input P file : model level

      character*80 ml_pfn

      real         ml_varmin(4),ml_varmax(4),ml_stag(4)

      integer      ml_vardim(4)

      real         ml_mdv

      integer      ml_ndim

      integer      ml_nx,ml_ny,ml_nz

      real         ml_xmin,ml_xmax,ml_ymin,ml_ymax,ml_dx,ml_dy

      integer      ml_ntimes

      real         ml_aklev(500),ml_bklev(500)

      real         ml_aklay(500),ml_bklay(500)

      real         ml_time

      real         ml_pollon,ml_pollat

      integer      ml_nvars

      character*80 ml_vnam(100)

      integer      ml_idate(5)

      real,allocatable, dimension (:,:)   :: ml_ps,ml_zb

      real,allocatable, dimension (:,:,:) :: ml_t3,ml_q3,ml_p3,ml_tv3

      real,allocatable, dimension (:,:,:) :: ml_z3

c     Variables for input Z file : pressure level

      character*80 pl_zfn

      real         pl_varmin(4),pl_varmax(4),pl_stag(4)

      integer      pl_vardim(4)

      real         pl_mdv

      integer      pl_ndim

      integer      pl_nx,pl_ny,pl_nz 

      real         pl_xmin,pl_xmax,pl_ymin,pl_ymax,pl_dx,pl_dy

      integer      pl_ntimes

      real         pl_aklev(500),pl_bklev(500)

      real         pl_aklay(500),pl_bklay(500)

      real         pl_time

      real         pl_pollon,pl_pollat

      integer      pl_nvars

      character*80 pl_vnam(100)

      integer      pl_idate(5)

      real,allocatable, dimension (:,:,:) :: pl_z3,pl_p3      

c     Variables for output Z file  : height level

      character*80 zl_ofn

      real         zl_varmin(4),zl_varmax(4),zl_stag(4)

      integer      zl_vardim(4)

      real         zl_mdv

      integer      zl_ndim

      integer      zl_nx,zl_ny,zl_nz 

      real         zl_xmin,zl_xmax,zl_ymin,zl_ymax,zl_dx,zl_dy

      integer      zl_ntimes

      real         zl_aklev(500),zl_bklev(500)

      real         zl_aklay(500),zl_bklay(500)

      real         zl_time

      real         zl_pollon,zl_pollat

      integer      zl_idate(5)    

      real,allocatable, dimension (:,:,:) :: zl_field

      real,allocatable, dimension (:,:,:) :: zl_p

c     Variables for input P,S file  : model level

      character*80 in_ofn

      real         in_varmin(4),in_varmax(4),in_stag(4)

      integer      in_vardim(4)

      real         in_mdv

      integer      in_ndim

      integer      in_nx,in_ny,in_nz 

      real         in_xmin,in_xmax,in_ymin,in_ymax,in_dx,in_dy

      integer      in_ntimes

      real         in_aklev(500),in_bklev(500)

      real         in_aklay(500),in_bklay(500)

      real         in_time

      real         in_pollon,in_pollat

      integer      in_nvars

      character*80 in_vnam(100)

      integer      in_idate(5)  

      real,allocatable, dimension (:,:,:) :: in_field

c     Physical and numerical parameters

      real      g

      parameter (g=9.80665)

      real      eps

      parameter (eps=0.01)

      real      tzero

      parameter (tzero=273.15)

      real      kappa

      parameter (kappa=0.6078)

      real      zerodiv

      parameter (zerodiv=0.0000000001)

      real      dpmin

      parameter (dpmin=10.)

      real      rdg

      parameter (rdg=29.271)

c     Flag for test mode

      integer      test

      parameter    (test=0)

      character*80 testfile

      parameter    (testfile='TEST')

c     Variables and levels for interpolation onto z levels

      character*80 levelfile,varfile

      integer      nvar,nlev

      character*80 varinp(100),varout(100),varsrc(100)

      real         zlev(500)

c     Auxiliary variables

      integer      ierr

      integer      cdfid,cstid

      character*80 cfn

      integer      stat

      real         time

      real         tv1(1000),z1(1000),p1(1000),f1(1000)

      real         spline_tv1(1000),spline_f1(1000),spline_z1(1000)

      real         pu,po,zu,zo,p,z,dp,p0,tvu,tvo,ff

      integer      i,j,k,l

      integer      lmin,n

      character*80 varname,cdfname

      integer      idate(5),stdate(5),datar(14)

      integer      isok

      character*80 name

      real         zmin,dz

c     -----------------------------------------------------------------

c     Read input fields

c     -----------------------------------------------------------------

      print*,'*********************************************************'

      print*,'* p2z                                                   *'

      print*,'*********************************************************'

c     Read in the parameter file

      open(10,file='fort.10')

       read(10,*) ml_pfn

       read(10,*) pl_zfn

       read(10,*) zl_ofn

       read(10,*) name,zmin

       if ( trim(name).ne.'GEO_ZMIN') stop

       read(10,*) name,nlev

       if ( trim(name).ne.'GEO_NZ'  ) stop

       read(10,*) name,dz

       if ( trim(name).ne.'GEO_DZ'  ) stop

       do i=1,nlev

          zlev(i)=zmin+real(i-1)*dz

       enddo

       nvar=1

 102   continue

        read(10,*,end=103) varinp(nvar),varout(nvar),varsrc(nvar)

        nvar=nvar+1

        goto 102

 103   continue

      nvar=nvar-1

      print*

      do i=1,nvar

        write(*,'(a10,a10,a30)') trim(varinp(i)),trim(varout(i)),

     >                           trim(varsrc(i))

      enddo

      print*

      close(10)

c     Get grid description for P file : model level

      call cdfopn(ml_pfn,cdfid,ierr)

      if (ierr.ne.0) goto 998

      call getcfn(cdfid,cfn,ierr)

      if (ierr.ne.0) goto 998

      call cdfopn(cfn,cstid,ierr)   

      if (ierr.ne.0) goto 998

      call getvars(cdfid,ml_nvars,ml_vnam,ierr)

      varname='T'

      isok=0

      call check_varok (isok,varname,ml_vnam,ml_nvars)

      if (isok.ne.1) goto 998

      call getdef(cdfid,varname,ml_ndim,ml_mdv,ml_vardim,

     >            ml_varmin,ml_varmax,ml_stag,ierr)

      if (ierr.ne.0) goto 998

      ml_nx  =ml_vardim(1)

      ml_ny  =ml_vardim(2)

      ml_nz  =ml_vardim(3)

      ml_xmin=ml_varmin(1)

      ml_ymin=ml_varmin(2)

      call getlevs(cstid,ml_nz,ml_aklev,ml_bklev,ml_aklay,ml_bklay,ierr)

      call getgrid(cstid,ml_dx,ml_dy,ierr)

      ml_xmax=ml_xmin+real(ml_nx-1)*ml_dx

      ml_ymax=ml_ymin+real(ml_ny-1)*ml_dy

      call gettimes(cdfid,ml_time,ml_ntimes,ierr) 

      call getstart(cstid,ml_idate,ierr)

      call getpole(cstid,ml_pollon,ml_pollat,ierr)

      call clscdf(cstid,ierr)

      call clscdf(cdfid,ierr) 

c     Get grid description for Z file : pressure level

      call cdfopn(pl_zfn,cdfid,ierr)

      if (ierr.ne.0) goto 998

      call getcfn(cdfid,cfn,ierr)

      if (ierr.ne.0) goto 998

      call cdfopn(cfn,cstid,ierr)   

      if (ierr.ne.0) goto 998

      call getvars(cdfid,pl_nvars,pl_vnam,ierr)

      varname='Z'

      isok=0

      call check_varok (isok,varname,pl_vnam,pl_nvars)

      if (isok.ne.1) goto 998

      call getdef(cdfid,varname,pl_ndim,pl_mdv,pl_vardim,

     >            pl_varmin,pl_varmax,pl_stag,ierr)

      if (ierr.ne.0) goto 998

      pl_nx  =pl_vardim(1)

      pl_ny  =pl_vardim(2)

      pl_nz  =pl_vardim(3)

      pl_xmin=pl_varmin(1)

      pl_ymin=pl_varmin(2)

      call getlevs(cstid,pl_nz,pl_aklev,pl_bklev,pl_aklay,pl_bklay,ierr)

      call getgrid(cstid,pl_dx,pl_dy,ierr)

      pl_xmax=pl_xmin+real(pl_nx-1)*pl_dx

      pl_ymax=pl_ymin+real(pl_ny-1)*pl_dy

      call gettimes(cdfid,pl_time,pl_ntimes,ierr)

      call getstart(cstid,pl_idate,ierr)

      call getpole(cstid,pl_pollon,pl_pollat,ierr)

      call clscdf(cstid,ierr)

      call clscdf(cdfid,ierr) 

c     Set grid description for output file : height level

      zl_vardim(1) = pl_vardim(1)

      zl_vardim(2) = pl_vardim(2)

      zl_vardim(3) = nlev

      zl_varmin(1) = pl_varmin(1)

      zl_varmin(2) = pl_varmin(2)

      zl_varmin(3) = zlev(1)

      zl_varmax(1) = pl_varmax(1)

      zl_varmax(2) = pl_varmax(2)

      zl_varmax(3) = zlev(nlev)

      do i=1,nlev

         zl_aklay(i) = zlev(i)        

         zl_bklay(i) = 0.

         zl_aklev(i) = zlev(i)

         zl_bklev(i) = 0.

      enddo

      zl_dx       = pl_dx

      zl_dy       = pl_dy

      zl_time     = pl_time

      zl_ntimes   = pl_ntimes

      zl_ndim     = 4

      zl_mdv      = pl_mdv

      zl_nx       = zl_vardim(1)

      zl_ny       = zl_vardim(2)

      zl_nz       = zl_vardim(3)

      zl_xmin     = zl_varmin(1)

      zl_ymin     = zl_varmin(2)

      zl_pollon   = ml_pollon

      zl_pollat   = ml_pollat

      do i=1,5

         zl_idate(i) = ml_idate(i)

      enddo

c     Consitency check for the grids

      if ( (ml_nx.ne.pl_nx).or.

     >     (ml_ny.ne.pl_ny).or.

     >     (abs(ml_xmin-pl_xmin    ).gt.eps).or.

     >     (abs(ml_ymin-pl_ymin    ).gt.eps).or.

     >     (abs(ml_xmax-pl_xmax    ).gt.eps).or.

     >     (abs(ml_ymax-pl_ymax    ).gt.eps).or.

     >     (abs(ml_dx  -pl_dx      ).gt.eps).or.

     >     (abs(ml_dy  -pl_dy      ).gt.eps).or.

     >     (abs(ml_time-pl_time    ).gt.eps).or.

     >     (abs(ml_pollon-pl_pollon).gt.eps).or.

     >     (abs(ml_pollat-pl_pollat).gt.eps)) then

         print*,'Input P and Z grids are not consistent... Stop'

         print*

         print*,'Xmin   : ',ml_xmin,pl_xmin

         print*,'Ymin   : ',ml_ymin,pl_ymin

         print*,'Xmax   : ',ml_xmax,pl_xmax

         print*,'Ymax   : ',ml_ymax,pl_ymax

         print*,'Dx     : ',ml_dx,  pl_dx

         print*,'Dy     : ',ml_dy,  pl_dy

         print*,'Time   : ',ml_time,pl_time

         print*,'Pollon : ',ml_pollon,pl_pollon

         print*,'Pollat : ',ml_pollat,pl_pollat

         stop

      endif

c     Allocate memory for all fields

      allocate(ml_ps(ml_nx,ml_ny),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array ml_ps ***'

      allocate(ml_zb(ml_nx,ml_ny),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array ml_zb ***'

      allocate(ml_p3(ml_nx,ml_ny,ml_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array ml_p3 ***'

      allocate(ml_t3(ml_nx,ml_ny,ml_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array ml_t3 ***'

      allocate(ml_q3(ml_nx,ml_ny,ml_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array ml_q3 ***'

      allocate(ml_tv3(ml_nx,ml_ny,ml_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array ml_tv3 ***'

      allocate(ml_z3(ml_nx,ml_ny,ml_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array ml_z3 ***'

      allocate(in_field(ml_nx,ml_ny,ml_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array in_field ***'

      allocate(pl_z3(pl_nx,pl_ny,pl_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array pl_z3 ***'

      allocate(pl_p3(pl_nx,pl_ny,pl_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array pl_p3 ***'

      allocate(zl_field(zl_nx,zl_ny,zl_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array zl_field ***'

      allocate(zl_p(zl_nx,zl_ny,zl_nz),stat=stat)

      if (stat.ne.0) print*,'*** error allocating array zl_p ***'

c     Read T, Q, PS from P file

      call cdfopn(ml_pfn,cdfid,ierr)

      if (ierr.ne.0) goto 998

      isok=0

      varname='T'

      call check_varok (isok,varname, ml_vnam,ml_nvars)

      varname='Q'

      call check_varok (isok,varname, ml_vnam,ml_nvars)

      varname='PS'

      call check_varok (isok,varname,ml_vnam,ml_nvars)

      if (isok.ne.3) goto 998

      print*,'R T  ',trim(ml_pfn)

      call getdat(cdfid,'T',ml_time,0,ml_t3,ierr)

      print*,'R Q  ',trim(ml_pfn)

      call getdat(cdfid,'Q',ml_time,0,ml_q3,ierr)

      print*,'R PS ',trim(ml_pfn)

      call getdat(cdfid,'PS',ml_time,1,ml_ps,ierr)

      call clscdf(cdfid,ierr)

c     Read Z from Z file

      call cdfopn(pl_zfn,cdfid,ierr)

      if (ierr.ne.0) goto 998

      isok=0

      varname='Z'

      call check_varok (isok,varname,pl_vnam,pl_nvars)

      if (isok.ne.1) goto 998

      print*,'R Z  ',trim(pl_zfn)

      call getdat(cdfid,varname,pl_time,0,pl_z3,ierr)

      call clscdf(cdfid,ierr)

c     Set the values for the pressure on the pressure levels

      do i=1,pl_nx

         do j=1,pl_ny

            do k=1,pl_nz

               pl_p3(i,j,k)=pl_aklay(k)

            enddo

         enddo

      enddo

c     -----------------------------------------------------------------

c     Calculate geopotential on layers

c     -----------------------------------------------------------------

c     Calculate 3d pressure field

      print*,'C P'

      do k=1,ml_nz

        do i=1,ml_nx

           do j=1,ml_ny

              ml_p3(i,j,k)=ml_aklay(k)+ml_bklay(k)*ml_ps(i,j)

            enddo

         enddo

      enddo

c     Calculate 3d virtual temperature

      print*,'C TV'

      do k=1,ml_nz

         do i=1,ml_nx

            do j=1,ml_ny

               ml_tv3(i,j,k) = (ml_t3(i,j,k)+tzero)*

     >                         (1.+kappa*ml_q3(i,j,k))

            enddo

         enddo

      enddo

c     Loop over all grid points

      print*,'C HYDROSTATIC EQUATION'

      do i=1,ml_nx

         do j=1,ml_ny

c           Make the virtual temperature profile available 

            do k=1,ml_nz

               p1 (ml_nz-k+1)=ml_p3 (i,j,k)

               tv1(ml_nz-k+1)=ml_tv3(i,j,k)

            enddo

            call spline (p1,tv1,ml_nz,1.e30,1.e30,spline_tv1)

c           Loop over all model levels

            do k=1,ml_nz

c              Get pressure at the grid point

               p = ml_p3(i,j,k)

c              Find nearest pressure level which is above topography

               lmin=pl_nz

               do l=1,pl_nz

                  if ((abs(p-pl_p3(i,j,l))).lt.(abs(p-pl_p3(i,j,lmin)))

     >                .and.

     >               (pl_p3(i,j,l).lt.ml_ps(i,j)) ) then

                     lmin=l

                  endif

               enddo

c              Integrate hydrostatic equation from this level to the grid point

               p0 = pl_p3(i,j,lmin)

               n  = nint(abs(p-p0)/dpmin)

               if (n.lt.1) n=1

               dp = (p-p0)/real(n)

               pu  = p0

               z   = pl_z3(i,j,lmin)

               call splint(p1,tv1,spline_tv1,ml_nz,pu,tvu)

               do l=1,n

                  po  = pu+dp

                  call splint(p1,tv1,spline_tv1,ml_nz,po,tvo)

                  z   = z + rdg*0.5*(tvu+tvo)*alog(pu/po)

                  tvu = tvo

                  pu  = po

               enddo

c              Set the geopotential at the grid point

               ml_z3(i,j,k) = z

            enddo

         enddo

      enddo

c     -----------------------------------------------------------------

c     Calculate height of topography

c     -----------------------------------------------------------------

      print*,'C TOPOGRAPHY'

      do i=1,ml_nx

         do j=1,ml_ny

c           Make the z/p profile available 

            do k=1,ml_nz

               p1(ml_nz-k+1)=ml_p3(i,j,k)

               z1(ml_nz-k+1)=ml_z3(i,j,k)

            enddo

c           Cubic spline interpolation

            call spline (p1,z1,ml_nz,1.e30,1.e30,spline_z1) 

            call splint (p1,z1,spline_z1,ml_nz,ml_ps(i,j),ml_zb(i,j))

         enddo

      enddo

c     -----------------------------------------------------------------

c     Interpolate pressure onto z levels

c     -----------------------------------------------------------------

      do i=1,zl_nx

         do j=1,zl_ny

c           Make 1d profile available 

            do k=1,ml_nz

               z1(k)=ml_z3(i,j,k)

               f1(k)=ml_p3(i,j,k)

            enddo

            call spline (z1,f1,ml_nz,1.e30,1.e30,spline_f1)

            do k=1,zl_nz

               if (zl_aklay(k).gt.ml_zb(i,j)) then

                  call splint(z1,f1,spline_f1,ml_nz,zl_aklay(k),ff)

                  zl_p(i,j,k)=ff

               else

                  zl_p(i,j,k)=zl_mdv

               endif

            enddo

         enddo

      enddo    

c     -----------------------------------------------------------------

c     Write output to netcdf file

c     -----------------------------------------------------------------

      if (test.eq.1) then

c        Create the output file (grid taken from temperature)

         cdfname=testfile

         call cdfopn(ml_pfn,cdfid,ierr)

         if (ierr.ne.0) goto 998

         call getcfn(cdfid,cfn,ierr)

         if (ierr.ne.0) goto 998

         call clscdf(cdfid,ierr)

         call crecdf(cdfname,cdfid,

     >               ml_varmin,ml_varmax,ml_ndim,cfn,ierr)

         if (ierr.ne.0) goto 997

c        Write the definitions of the output variables

         varname='PS'

         ml_vardim(3)=1

         call putdef(cdfid,varname,ml_ndim,ml_mdv,

     >               ml_vardim,ml_varmin,ml_varmax,ml_stag,ierr)

         if (ierr.ne.0) goto 997

         varname='ORO'

         call putdef(cdfid,varname,ml_ndim,ml_mdv,

     >               ml_vardim,ml_varmin,ml_varmax,ml_stag,ierr)

         if (ierr.ne.0) goto 997

         ml_vardim(3)=ml_nz

         varname='Z'

         call putdef(cdfid,varname,ml_ndim,ml_mdv,ml_vardim,

     >               ml_varmin,ml_varmax,ml_stag,ierr)

         if (ierr.ne.0) goto 997

c        Write output fields

         print*,'W PS TEST'

         varname='PS'

         call putdat(cdfid,varname,ml_time,1,ml_ps,ierr)

         if (ierr.ne.0) goto 997

         print*,'W ZB TEST'

         varname='ORO'

         call putdat(cdfid,varname,ml_time,1,ml_zb,ierr)

         if (ierr.ne.0) goto 997

         print*,'W Z  TEST'

         varname='Z'

         call putdat(cdfid,varname,ml_time,0,ml_z3,ierr)

         if (ierr.ne.0) goto 997

c        Close cdf file

         call clscdf(cdfid,ierr)

      endif

c     -----------------------------------------------------------------

c     Interpolate fields onto a stack of z levels and write new file

c     -----------------------------------------------------------------

c     Create output file

      cfn=trim(zl_ofn)//'_cst'

      call crecdf(trim(zl_ofn),cdfid,zl_varmin,zl_varmax,

     >            zl_ndim,trim(cfn),ierr)

      if (ierr.ne.0) goto 995

c     Write topography

      print*,'W ZB ',trim(zl_ofn)

      varname='ORO'

      zl_vardim(3)=1

      call putdef(cdfid,varname,zl_ndim,zl_mdv,zl_vardim,

     >            zl_varmin,zl_varmax,zl_stag,ierr)         

      zl_vardim(3)=zl_nz

      if (ierr.ne.0) goto 995

      call putdat(cdfid,varname,zl_time,1,ml_zb,ierr)

      if (ierr.ne.0) goto 995

c     Write pressure

      print*,'W  P  ',trim(zl_ofn)

      varname='P'

      call putdef(cdfid,varname,4,zl_mdv,zl_vardim,

     >            zl_varmin,zl_varmax,zl_stag,ierr)         

      if (ierr.ne.0) goto 995

      call putdat(cdfid,varname,zl_time,0,zl_p,ierr)

      if (ierr.ne.0) goto 995

c     Close output file

      call clscdf(cdfid,ierr)

c     Loop over all variables

      do l=1,nvar

         print*,'I ',trim(varinp(l))

c        Get grid description for variable 

         call cdfopn(varsrc(l),cdfid,ierr)

         if (ierr.ne.0) goto 996

         call getcfn(cdfid,cfn,ierr)

         if (ierr.ne.0) goto 996

         call cdfopn(cfn,cstid,ierr)   

         if (ierr.ne.0) goto 996

         call getvars(cdfid,in_nvars,in_vnam,ierr)

         isok=0

         varname=varinp(l)

         call check_varok (isok,varname, in_vnam,in_nvars)

         if (isok.ne.1) goto 996

         call getdef(cdfid,varinp(l),in_ndim,in_mdv,in_vardim,

     >               in_varmin,in_varmax,in_stag,ierr)

         if (ierr.ne.0) goto 996

         in_nx  =in_vardim(1)

         in_ny  =in_vardim(2)

         in_nz  =in_vardim(3)

         in_xmin=in_varmin(1)

         in_ymin=in_varmin(2)

         call getlevs(cstid,in_nz,in_aklev,in_bklev,

     >                in_aklay,in_bklay,ierr)

         call getgrid(cstid,in_dx,in_dy,ierr)

         in_xmax=in_xmin+real(in_nx-1)*in_dx

         in_ymax=in_ymin+real(in_ny-1)*in_dy

         call gettimes(cdfid,in_time,in_ntimes,ierr) 

         call getstart(cstid,in_idate,ierr)

         call getpole(cstid,in_pollon,in_pollat,ierr)

         call clscdf(cstid,ierr)

         call clscdf(cdfid,ierr) 

c        Check whether this grid is consistent with P grid 

         if ( (ml_nx.ne.in_nx).or.

     >        (ml_ny.ne.in_ny).or.

     >        (ml_nz.ne.in_nz).or.

     >        (abs(ml_xmin-in_xmin      ).gt.eps).or.

     >        (abs(ml_ymin-in_ymin      ).gt.eps).or.

     >        (abs(ml_xmax-in_xmax      ).gt.eps).or.

     >        (abs(ml_ymax-in_ymax      ).gt.eps).or.

     >        (abs(ml_dx  -in_dx        ).gt.eps).or.

     >        (abs(ml_dy  -in_dy        ).gt.eps).or.

     >        (abs(ml_time-in_time      ).gt.eps).or.

     >        (abs(ml_stag(1)-in_stag(1)).gt.eps).or.

     >        (abs(ml_stag(2)-in_stag(2)).gt.eps).or.

     >        (abs(ml_stag(3)-in_stag(3)).gt.eps).or.

     >        (abs(ml_pollon-in_pollon  ).gt.eps).or.

     >        (abs(ml_pollat-in_pollat  ).gt.eps)) then

            print*,trim(varinp(l)),

     >            ' :Input P and FIELD grids are not consistent... Stop'

            print*,'Stag: ',ml_stag, in_stag

            print*,'Pol:  ',ml_pollon,in_pollon,ml_pollat,in_pollat

            stop

         endif

c        Read variable from file

         call cdfopn(varsrc(l),cdfid,ierr)

         if (ierr.ne.0) goto 996

         call getdat(cdfid,varinp(l),in_time,0,in_field,ierr)

         if (ierr.ne.0) goto 996

         call clscdf(cdfid,ierr) 

c        Write the constants file

         if (l.eq.1) then

            datar(1)=zl_nx

            datar(2)=zl_ny  

            datar(3)=int(1000.*zl_varmax(2))

            datar(4)=int(1000.*zl_varmin(1))

            datar(5)=int(1000.*zl_varmin(2))

            datar(6)=int(1000.*zl_varmax(1))

            datar(7)=int(1000.*zl_dx)

            datar(8)=int(1000.*zl_dy)

            datar(9)=zl_nz

            datar(10)=1

            datar(11)=1      

            datar(12)=0      

            datar(13)=int(1000.*zl_pollon) 

            datar(14)=int(1000.*zl_pollat) 

            cfn=trim(zl_ofn)//'_cst'

            call wricst(cfn,datar,zl_aklev,zl_bklev,

     >                  zl_aklay,zl_bklay,zl_idate)

         endif

c        Do the interpolation

         do i=1,zl_nx

            do j=1,zl_ny

c              Make 1d profile available 

               do k=1,ml_nz

                  z1(k)=ml_z3   (i,j,k)

                  f1(k)=in_field(i,j,k)

               enddo

               call spline (z1,f1,ml_nz,1.e30,1.e30,spline_f1)

               do k=1,zl_nz

                  if (zl_aklay(k).gt.ml_zb(i,j)) then

                     call splint(z1,f1,spline_f1,ml_nz,zl_aklay(k),ff)

                     zl_field(i,j,k)=ff

                  else

                     zl_field(i,j,k)=zl_mdv

                  endif

               enddo

            enddo

         enddo

c        Write the output field

         print*,'W ',trim(varout(l)),' ',trim(zl_ofn)

         call cdfwopn(trim(zl_ofn),cdfid,ierr)

         varname=trim(varout(l))

         call putdef(cdfid,varname,4,zl_mdv,zl_vardim,

     >               zl_varmin,zl_varmax,zl_stag,ierr)         

         if (ierr.ne.0) goto 995

         call putdat(cdfid,varname,zl_time,0,zl_field,ierr)

         if (ierr.ne.0) goto 995

         call clscdf(cdfid,ierr)

      enddo

c     -----------------------------------------------------------------

c     Write topography and geopotential also to the input P file

c     -----------------------------------------------------------------

c     Open the P file

      call cdfwopn(trim(ml_pfn),cdfid,ierr)     

c     Write topography

      varname='ORO'

      print*,'W ',trim(varname),' ',trim(ml_pfn)

      isok=0

      call check_varok (isok,varname,ml_vnam,ml_nvars)

      if (isok.eq.0) then

         ml_vardim(3)=1

         call putdef(cdfid,varname,ml_ndim,ml_mdv,ml_vardim,

     >               ml_varmin,ml_varmax,ml_stag,ierr)         

         ml_vardim(3)=ml_nz

         if (ierr.ne.0) goto 997

      endif

      call putdat(cdfid,varname,ml_time,1,ml_zb,ierr)

      if (ierr.ne.0) goto 997

c     Write geopotential height

      varname='Z'

      print*,'W ',trim(varname),' ',trim(ml_pfn)

      isok=0

      call check_varok (isok,varname,ml_vnam,ml_nvars)

      if (isok.eq.0) then

         call putdef(cdfid,varname,ml_ndim,ml_mdv,ml_vardim,

     >               ml_varmin,ml_varmax,ml_stag,ierr)         

         if (ierr.ne.0) goto 997

      endif

      call putdat(cdfid,varname,ml_time,0,ml_z3,ierr)

      if (ierr.ne.0) goto 997

c     Close P file

      call clscdf(cdfid,ierr)

c     -----------------------------------------------------------------

c     Exception handling and format specs

c     -----------------------------------------------------------------

      stop

 998  print*,'Z: Problems with input from m level'

      stop

 997  print*,'Z: Problems with output on m level'

      stop

 996  print*,'F: Problems with input from m level'

      stop

 995  print*,'F: Problems with output on z level'

      stop

      end

c     -------------------------------------------------------------

c     Natural cubic spline

c     -------------------------------------------------------------

      SUBROUTINE spline(x,y,n,yp1,ypn,y2)

      INTEGER n,NMAX

      REAL yp1,ypn,x(n),y(n),y2(n)

      PARAMETER (NMAX=500)

      INTEGER i,k

      REAL p,qn,sig,un,u(NMAX)

      if (yp1.gt..99e30) then

        y2(1)=0.

        u(1)=0.

      else

        y2(1)=-0.5

        u(1)=(3./(x(2)-x(1)))*((y(2)-y(1))/(x(2)-x(1))-yp1)

      endif

      do 11 i=2,n-1

        sig=(x(i)-x(i-1))/(x(i+1)-x(i-1))

        p=sig*y2(i-1)+2.

        y2(i)=(sig-1.)/p

        u(i)=(6.*((y(i+1)-y(i))/(x(i+

     *1)-x(i))-(y(i)-y(i-1))/(x(i)-x(i-1)))/(x(i+1)-x(i-1))-sig*

     *u(i-1))/p

11    continue

      if (ypn.gt..99e30) then

        qn=0.

        un=0.

      else

        qn=0.5

        un=(3./(x(n)-x(n-1)))*(ypn-(y(n)-y(n-1))/(x(n)-x(n-1)))

      endif

      y2(n)=(un-qn*u(n-1))/(qn*y2(n-1)+1.)

      do 12 k=n-1,1,-1

        y2(k)=y2(k)*y2(k+1)+u(k)

12    continue

      return

      END

      SUBROUTINE splint(xa,ya,y2a,n,x,y)

      INTEGER n

      REAL x,y,xa(n),y2a(n),ya(n)

      INTEGER k,khi,klo

      REAL a,b,h

      klo=1

      khi=n

1     if (khi-klo.gt.1) then

        k=(khi+klo)/2

        if(xa(k).gt.x)then

          khi=k

        else

          klo=k

        endif

      goto 1

      endif

      h=xa(khi)-xa(klo)

      if (h.eq.0.) pause 'bad xa input in splint'

      a=(xa(khi)-x)/h

      b=(x-xa(klo))/h

      y=a*ya(klo)+b*ya(khi)+((a**3-a)*y2a(klo)+(b**3-b)*y2a(khi))*(h**

     *2)/6.

      return

      END

c     ----------------------------------------------------------------

c     Check whether variable is found on netcdf file

c     ----------------------------------------------------------------

      subroutine check_varok (isok,varname,varlist,nvars)

c     Check whether the variable <varname> is in the list <varlist(nvars)>. 

c     If this is the case, <isok> is incremented by 1. Otherwise <isok> 

c     keeps its value.

      implicit none

c     Declaraion of subroutine parameters

      integer      isok

      integer      nvars

      character*80 varname

      character*80 varlist(nvars)

c     Auxiliary variables

      integer      i

c     Main

      do i=1,nvars

         if (trim(varname).eq.trim(varlist(i))) isok=isok+1

      enddo

      end