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c ************************************************************
c * This package provides input routines to read the wind *
c * and other fields from IVE necdf files. The routines are *
c * *
c * 1) input_open : to open a data file *
c * 2) input_grid : to read the grid information, including *
c * the vertical levels *
c * 3) input_wind : to read the wind components *
c * 4) input_close : to close an input file *
c * *
c * The file is characterised by an filename <filename> and *
c * a file identifier <fid>. The horizontal grid is given by *
c * <xmin,xmax,ymin,ymax,dx,dy,nx,ny> where the pole of the *
c * rotated grid is given by <pollon,pollat>. The vertical *
c * grid is characterised by the surface pressure <ps> and *
c * the pressure at staggered <slev> and unstaggered <ulev> *
c * levels. The number of levels is given by <nz>. Finally, *
c * the retrieval of the wind <field> with name <fieldname> *
c * is characterised by a <time> and a missing data value *
c * <mdv>. *
c * *
c * Author: Michael Sprenger, Autumn 2008 *
c ************************************************************
c ------------------------------------------------------------
c Open input file
c ------------------------------------------------------------
subroutine input_open (fid,filename)
c Open the input file with filename <filename> and return the
c file identifier <fid> for further reference.
use netcdf
implicit none
c Declaration of subroutine parameters
integer fid ! File identifier
character*80 filename ! Filename
c Declaration of auxiliary variables
integer ierr
c Open netcdf file
ierr = NF90_OPEN(TRIM(filename),nf90_nowrite, fid)
IF ( ierr /= nf90_NoErr ) PRINT *,NF90_STRERROR(ierr)
c Exception handling
return
end
c ------------------------------------------------------------
c Read information about the grid
c ------------------------------------------------------------
subroutine input_grid
> (fid,fieldname,xmin,xmax,ymin,ymax,dx,dy,nx,ny,
> time,pollon,pollat,p3,ps,nz,ak,bk,stagz,
> timecheck)
c Read grid information at <time> from file with identifier <fid>.
c The horizontal grid is characterized by <xmin,xmax,ymin,ymax,dx,dy>
c with pole position at <pollon,pollat> and grid dimension <nx,ny>.
c The 3d arrays <p3(nx,ny,nz)> gives the vertical coordinates, either
c on the staggered or unstaggered grid (with <stagz> as the flag).
c The surface pressure is given in <ps(nx,ny)>. If <fid> is negative,
c only the grid dimensions and grid parameters (xmin...pollat,nz) are
c determined and returned (this is needed for dynamical allocation of
c memory).
use netcdf
implicit none
c Declaration of subroutine parameters
integer fid ! File identifier
real xmin,xmax,ymin,ymax ! Domain size
real dx,dy ! Horizontal resolution
integer nx,ny,nz ! Grid dimensions
real pollon,pollat ! Longitude and latitude of pole
real p3(nx,ny,nz) ! Staggered levels
real ps(nx,ny) ! Surface pressure
real time ! Time of the grid information
real ak(nz),bk(nz) ! Ak and Bk for layers or levels
real stagz ! Vertical staggering (0 or -0.5)
character*80 fieldname ! Variable from which to take grid info
character*80 timecheck ! Either 'yes' or 'no'
c Numerical and physical parameters
real eps ! Numerical epsilon
parameter (eps=0.001)
c Netcdf variables
integer vardim(4)
real varmin(4),varmax(4)
real mdv
real stag(4)
integer ndim
character*80 cstfile
integer cstid
integer nvars
character*80 vars(100)
integer dimids (nf90_max_var_dims),dimid
character*80 dimname(nf90_max_var_dims)
character*80 stdname
real,allocatable, dimension (:) :: lon,lat,lev
real,allocatable, dimension (:) :: times
real,allocatable, dimension (:,:) :: tmp2
real,allocatable, dimension (:,:,:) :: tmp3
real,allocatable, dimension (:) :: aktmp,bktmp
character*80 units
character*80 leveltype
integer nakbktmp
integer vertical_swap
c Auxiliary variables
integer ierr
integer i,j,k
integer isok
real tmp(200)
character*80 varname
real rtime
integer varid
integer cdfid
integer stat
real delta
integer closear
real maxps,minps
c ---- Read data from netCDF file as they are ---------------------
c Set file identifier
if (fid.lt.0) then
cdfid = -fid
else
cdfid = fid
endif
c Special handling if 3D pressure is
if ( fieldname.eq.'P' ) then
fieldname = 'U'
endif
c Get number of dimensions of variable -> ndim
ierr = NF90_INQ_VARID(cdfid,fieldname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_inquire_variable(cdfid, varid, ndims = ndim)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
if ( ndim.ne.4 ) then
print*,' ERROR: netCDF variables need to be 4D'
print*,' ',trim(fieldname)
stop
endif
c Get dimensions -> vardim(1:ndim),dimname(1:ndim)
ierr = NF90_INQ_VARID(cdfid,fieldname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_inquire_variable(cdfid, varid,
> dimids = dimids(1:ndim))
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
do i=1,ndim
ierr = nf90_inquire_dimension(cdfid, dimids(i),
> name = dimname(i) )
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_inquire_dimension(cdfid, dimids(i),len=vardim(i))
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
enddo
c Get dimension of AK,BK
varname = 'nhym'
ierr = NF90_INQ_DIMID(cdfid,varname,dimid)
ierr = nf90_inquire_dimension(cdfid, dimid,len=nakbktmp)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c Check whether the list of dimensions is OK
if ( ( dimname(1).ne.'lon' ).or.
> ( dimname(2).ne.'lat' ).or.
> ( dimname(3).ne.'lev' ).and.( dimname(3).ne.'lev_2' ).or.
> ( dimname(4).ne.'time' ) )
>then
print*,' ERROR: the dimensions of the variable are not correct'
print*,' expected -> lon / lat / lev / time'
print*, ( trim(dimname(i))//' / ',i=1,ndim )
stop
endif
c Check about the type of vertical levels
varname=dimname(3)
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_att(cdfid, varid, "standard_name", leveltype)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
if ( (leveltype.ne.'hybrid_sigma_pressure').and.
> (leveltype.ne.'air_pressure' ) )
>then
print*,' ERROR: input netCDF data must be on hybrid-sigma'
print*,' or air pressure levels!',trim(leveltype)
stop
endif
c Allocate memory for reading arrays
allocate(tmp2(vardim(1),vardim(2)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array tmp2 ***'
allocate(tmp3(vardim(1),vardim(2),vardim(3)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array tmp3 ***'
allocate(lon(vardim(1)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array lon ***'
allocate(lat(vardim(2)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array lat ***'
allocate(lev(vardim(3)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array lev ***'
allocate(times(vardim(4)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array times ***'
allocate(aktmp(nakbktmp),stat=stat)
if (stat.ne.0) print*,'*** error allocating array aktmp ***'
allocate(bktmp(nakbktmp),stat=stat)
if (stat.ne.0) print*,'*** error allocating array bktmp ***'
c Get domain longitudes, latitudes and levels
varname = dimname(1)
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(cdfid,varid,lon)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
varname = dimname(2)
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(cdfid,varid,lat)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
varname = dimname(3)
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(cdfid,varid,lev)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c Get ak and bk
varname='hyam'
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(cdfid,varid,aktmp)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
varname='hybm'
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(cdfid,varid,bktmp)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c Check that unit of ak is in hPa - if necessary correct it
varname='hyam'
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_att(cdfid, varid, "units", units)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
if ( units.eq.'Pa' ) then
do k=1,nakbktmp
aktmp(k) = 0.01 * aktmp(k)
enddo
endif
c Check that unit of lev is in hPa - if necessary correct it
if ( leveltype.eq.'air_pressure' ) then
varname='lev'
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_att(cdfid, varid, "units", units)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
if ( units.eq.'Pa' ) then
do k=1,vardim(3)
lev(k) = 0.01 * lev(k)
enddo
endif
endif
c Decide whether to swap vertical levels - highest pressure at index 1
vertical_swap = 1
if ( leveltype.eq.'hybrid_sigma_pressure') then
if ( (aktmp(1) + bktmp(1) * 1000.).gt.
> (aktmp(2) + bktmp(2) * 1000.) )
> then
vertical_swap = 0
endif
elseif ( leveltype.eq.'air_pressure') then
if ( lev(1).gt.lev(2) ) then
vertical_swap = 0
endif
endif
c print*,' Vertical SWAP P -> ', vertical_swap
c Get time information (check if time is correct)
varname = 'time'
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(cdfid,varid,times)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
isok=0
do i=1,vardim(4)
if (abs(time-times(i)).lt.eps) then
isok = 1
rtime = times(i)
elseif (timecheck.eq.'no') then
isok = 1
rtime = times(1)
endif
enddo
if ( isok.eq.0 ) then
print*,' ERROR: time ',rtime,' not found on netCDF file'
stop
endif
c Read surface pressure
varname='PS'
ierr = NF90_INQ_VARID(cdfid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(cdfid,varid,tmp2)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c Check that surface pressure is in hPa
maxps = -1.e19
minps = 1.e19
do i=1,vardim(1)
do j=1,vardim(2)
if (tmp2(i,j).gt.maxps) maxps = tmp2(i,j)
if (tmp2(i,j).lt.minps) minps = tmp2(i,j)
enddo
enddo
if ( (maxps.gt.1500.).or.(minps.lt.300.) ) then
print*,' ERROR: surface pressre PS must be in hPa'
print*,' ',maxps,minps
stop
endif
c ---- Define output of subroutine --------------------------------
c If not full list of vertical levels, reduce AK,BK arrays
if ( (leveltype.eq.'hybrid_sigma_pressure').and.
> (nakbktmp.ne.vardim(3) ) )
>then
print*,' WARNING: only subset of vertical levels used...'
do k=1,vardim(3)
if ( vertical_swap.eq.1 ) then
aktmp(k) = aktmp( k+nakbktmp-vardim(3) )
bktmp(k) = bktmp( k+nakbktmp-vardim(3) )
endif
enddo
endif
c Set the grid dimensions and constants
nx = vardim(1)
ny = vardim(2)
nz = vardim(3)
xmin = lon(1)
ymin = lat(1)
xmax = lon(nx)
ymax = lat(ny)
dx = (xmax-xmin)/real(nx-1)
dy = (ymax-ymin)/real(ny-1)
pollon = 0.
pollat = 90.
stagz = 0.
delta = xmax-xmin-360.
if (abs(delta+dx).lt.eps) then
xmax = xmax + dx
nx = nx + 1
closear = 1
else
closear = 0
endif
c Save the output arrays (if fid>0) - close arrays on request
if ( fid.gt.0 ) then
c Calculate layer pressures
if (leveltype.eq.'hybrid_sigma_pressure' ) then
do i=1,vardim(1)
do j=1,vardim(2)
do k=1,vardim(3)
tmp3(i,j,k)=aktmp(k)+bktmp(k)*tmp2(i,j)
enddo
enddo
enddo
elseif (leveltype.eq.'air_pressure' ) then
do i=1,vardim(1)
do j=1,vardim(2)
do k=1,vardim(3)
tmp3(i,j,k)=lev(k)
enddo
enddo
enddo
endif
c Get PS - close array on demand
do j=1,vardim(2)
do i=1,vardim(1)
ps(i,j) = tmp2(i,j)
enddo
if (closear.eq.1) ps(vardim(1)+1,j) = ps(1,j)
enddo
c Get P3 - close array on demand + vertical swap
do j=1,vardim(2)
do k=1,vardim(3)
do i=1,vardim(1)
if ( vertical_swap.eq.1 ) then
p3(i,j,k) = tmp3(i,j,vardim(3)-k+1)
else
p3(i,j,k) = tmp3(i,j,k)
endif
enddo
if (closear.eq.1) p3(vardim(1)+1,j,k) = p3(1,j,k)
enddo
enddo
c Get AK,BK - vertical swap on demand
if ( leveltype.eq.'hybrid_sigma_pressure' ) then
do k=1,vardim(3)
if ( vertical_swap.eq.1 ) then
ak(k) = aktmp(vardim(3)-k+1)
bk(k) = bktmp(vardim(3)-k+1)
endif
enddo
elseif (leveltype.eq.'air_pressure' ) then
do k=1,vardim(3)
if ( vertical_swap.eq.1 ) then
ak(k) = lev(vardim(3)-k+1)
bk(k) = 0.
else
ak(k) = lev(k)
bk(k) = 0.
endif
enddo
endif
endif
return
end
c ------------------------------------------------------------
c Read wind information
c ------------------------------------------------------------
subroutine input_wind (fid,fieldname,field,time,stagz,mdv,
> xmin,xmax,ymin,ymax,dx,dy,nx,ny,nz,
> timecheck)
c Read the wind component <fieldname> from the file with identifier
c <fid> and save it in the 3d array <field>. The vertical staggering
c information is provided in <stagz> and gives the reference to either
c the layer or level field from <input_grid>. A consistency check is
c performed to have an agreement with the grid specified by <xmin,xmax,
c ymin,ymax,dx,dy,nx,ny,nz>.
use netcdf
implicit none
c Declaration of variables and parameters
integer fid ! File identifier
character*80 fieldname ! Name of the wind field
integer nx,ny,nz ! Dimension of fields
real field(nx,ny,nz) ! 3d wind field
real stagz ! Staggering in the z direction
real mdv ! Missing data flag
real xmin,xmax,ymin,ymax ! Domain size
real dx,dy ! Horizontal resolution
real time ! Time
character*80 timecheck ! Either 'yes' or 'no'
c Numerical and physical parameters
real eps ! Numerical epsilon
parameter (eps=0.001)
real notimecheck ! 'Flag' for no time check
parameter (notimecheck=7.26537)
c Netcdf variables
integer ierr
character*80 varname
integer vardim(4)
real varmin(4),varmax(4)
real stag(4)
integer ndim
real times(10)
integer ntimes
character*80 cstfile
integer cstid
real aklay(200),bklay(200),aklev(200),bklev(200)
real ps(nx,ny)
integer dimids (nf90_max_var_dims)
character*80 dimname(nf90_max_var_dims)
integer varid
integer cdfid
real,allocatable, dimension (:) :: lon,lat,lev
real,allocatable, dimension (:,:) :: tmp2
real,allocatable, dimension (:,:,:) :: tmp3
real,allocatable, dimension (:) :: aktmp,bktmp
character*80 leveltype
integer vertical_swap
character*80 units
integer nakbktmp
integer dimid
c Auxiliary variables
integer isok
integer i,j,k
integer nz1
real rtime
integer closear
integer stat
real delta
c Init mdv
mdv = -999.
c Get the number of dimensions -> ndim
ierr = NF90_INQ_VARID(fid,fieldname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_inquire_variable(fid, varid, ndims = ndim)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c Get the dimensions of the arrays -> varid(1:ndim)
ierr = NF90_INQ_VARID(fid,fieldname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_inquire_variable(fid, varid,
> dimids = dimids(1:ndim))
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
do i=1,ndim
ierr = nf90_inquire_dimension(fid, dimids(i),
> name = dimname(i) )
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_inquire_dimension(fid, dimids(i),len=vardim(i))
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
enddo
c Check whether the list of dimensions is OK
if ( ( dimname(1).ne.'lon' ).or.
> ( dimname(2).ne.'lat' ).or.
> ( dimname(3).ne.'lev' ).and.( dimname(3).ne.'lev_2' ).or.
> ( dimname(4).ne.'time' ) )
>then
print*,' ERROR: the dimensions of the variable are not correct'
print*,' expected -> lon / lat / lev / time'
print*, ( trim(dimname(i))//' / ',i=1,ndim )
stop
endif
c Get dimension of AK,BK
varname = 'nhym'
ierr = NF90_INQ_DIMID(fid,varname,dimid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_inquire_dimension(fid, dimid,len=nakbktmp)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c Check about the type of vertical levels
varname=dimname(3)
ierr = NF90_INQ_VARID(fid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_att(fid, varid, "standard_name", leveltype)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
if ( (leveltype.ne.'hybrid_sigma_pressure').and.
> (leveltype.ne.'air_pressure' ) )
>then
print*,' ERROR: input netCDF data must be on hybrid-sigma'
print*,' or air pressure levels!',trim(leveltype)
stop
endif
c Allocate memory for reading arrays - depending on <closear>
allocate(tmp2(vardim(1),vardim(2)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array tmp2 ***'
allocate(tmp3(vardim(1),vardim(2),vardim(3)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array tmp3 ***'
allocate(lon(vardim(1)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array lon ***'
allocate(lat(vardim(2)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array lat ***'
allocate(lev(vardim(3)),stat=stat)
if (stat.ne.0) print*,'*** error allocating array lev ***'
allocate(aktmp(nakbktmp),stat=stat)
if (stat.ne.0) print*,'*** error allocating array aktmp ***'
allocate(bktmp(nakbktmp),stat=stat)
if (stat.ne.0) print*,'*** error allocating array bktmp ***'
c Get domain boundaries - longitude, latitude, levels
varname = dimname(1)
ierr = NF90_INQ_VARID(fid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(fid,varid,lon)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
varname = dimname(2)
ierr = NF90_INQ_VARID(fid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(fid,varid,lat)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
varname = dimname(3)
ierr = NF90_INQ_VARID(fid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(fid,varid,lev)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c Get ak and bk
varname='hyam'
ierr = NF90_INQ_VARID(fid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(fid,varid,aktmp)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
varname='hybm'
ierr = NF90_INQ_VARID(fid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(fid,varid,bktmp)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c Check that unit of ak is in hPa - if necessary correct it
varname='hyam'
ierr = NF90_INQ_VARID(fid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_att(fid, varid, "units", units)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
if ( units.eq.'Pa' ) then
do k=1,nakbktmp
aktmp(k) = 0.01 * aktmp(k)
enddo
endif
c Check that unit of lev is in hPa - if necessary correct it
if ( leveltype.eq.'air_pressure' ) then
varname='lev'
ierr = NF90_INQ_VARID(fid,varname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_att(fid, varid, "units", units)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
if ( units.eq.'Pa' ) then
do k=1,vardim(3)
lev(k) = 0.01 * lev(k)
enddo
endif
endif
c Decide whether to swap vertical levels
vertical_swap = 1
if ( leveltype.eq.'hybrid_sigma_pressure') then
if ( (aktmp(1) + bktmp(1) * 1000.).gt.
> (aktmp(2) + bktmp(2) * 1000.) )
> then
vertical_swap = 0
endif
elseif ( leveltype.eq.'air_pressure') then
if ( lev(1).gt.lev(2) ) then
vertical_swap = 0
endif
endif
c Read data
ierr = NF90_INQ_VARID(fid,fieldname,varid)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
ierr = nf90_get_var(fid,varid,tmp3)
IF(ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
c If the field is 2D, expand it to 3D - simple handling of 2D tracing
if ( vardim(3).eq.1 ) then
do i=1,vardim(1)
do j=1,vardim(2)
do k=1,vardim(3)
tmp3(i,j,k) = tmp3(i,j,1)
enddo
enddo
enddo
endif
c Decide whether to close arrays
delta = varmax(1)-varmin(1)-360.
if (abs(delta+dx).lt.eps) then
closear = 1
else
closear = 0
endif
c Save output array - close array and swap on demand
do j=1,vardim(2)
do k=1,vardim(3)
do i=1,vardim(1)
if ( vertical_swap.eq.1 ) then
field(i,j,k) = tmp3(i,j,vardim(3)-k+1)
else
field(i,j,k) = tmp3(i,j,k)
endif
enddo
if (closear.eq.1) field(vardim(1)+1,j,k) = field(1,j,k)
enddo
enddo
c Exit point
return
end
c ------------------------------------------------------------
c Close input file
c ------------------------------------------------------------
subroutine input_close(fid)
c Close the input file with file identifier <fid>.
use netcdf
implicit none
c Declaration of subroutine parameters
integer fid
c Auxiliary variables
integer ierr
c Close file
ierr = NF90_CLOSE(fid)
IF( ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
end
c ------------------------------------------------------------
c Get a list of variables on netCDF file
c ------------------------------------------------------------
subroutine input_getvars(fid,vnam,nvars)
c List of variables on netCDF file
use netcdf
implicit none
c Declaration of subroutine parameters
integer fid
integer nvars
character*80 vnam(200)
c Auxiliary variables
integer ierr
integer i
integer nDims,nGlobalAtts,unlimdimid
ierr = nf90_inquire(fid, nDims, nVars, nGlobalAtts, unlimdimid)
IF( ierr /= nf90_NoErr) PRINT *,NF90_STRERROR(ierr)
do i=1,nVars
ierr = nf90_inquire_variable(fid, i, name = vnam(i))
enddo
end