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CACmb/src/io.f90

761 lines
28 KiB

module io
use elements
use parameters
use atoms
use box
implicit none
integer :: outfilenum = 0, infilenum = 0
character(len=100) :: outfiles(100), infiles(100)
logical :: force_overwrite
public
contains
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! Subroutines for writing out data files !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
subroutine get_out_file(filename)
implicit none
character(len=100), intent(in) :: filename
character(len=100) :: temp_outfile
character(len=1) :: overwrite
logical :: file_exists
!If no filename is provided then this function is called with none and prompts user input
if (filename=='none') then
print *, "Please specify a filename or extension to output to:"
read(*,*) temp_outfile
else
temp_outfile = filename
end if
!Infinite loop which only exists if user provides valid filetype
overwrite = 'r'
do while(.true.)
!Check to see if file exists, if it does then ask user if they would like to overwrite the file
inquire(file=trim(temp_outfile), exist=file_exists)
if (file_exists.and.(.not.(force_overwrite))) then
if (overwrite == 'r') print *, "File ", trim(temp_outfile), " already exists. Would you like to overwrite? (Y/N)"
read(*,*) overwrite
if((scan(overwrite, "n") > 0).or.(scan(overwrite, "N") > 0)) then
print *, "Please specify a new filename with extension:"
read(*,*) temp_outfile
else if((scan(overwrite, "y") > 0).or.(scan(overwrite, "Y") > 0)) then
continue
else
print *, "Please pick either y or n"
read(*,*) overwrite
end if
end if
if (scan(temp_outfile,'.',.true.) == 0) then
print *, "No extension included on filename, please type a full filename that includes an extension."
read(*,*) temp_outfile
cycle
end if
select case(temp_outfile(scan(temp_outfile,'.',.true.)+1:))
case('xyz', 'lmp', 'vtk', 'mb', 'restart')
outfilenum=outfilenum+1
outfiles(outfilenum) = temp_outfile
exit
case('cac')
lmpcac = .true.
outfilenum=outfilenum+1
outfiles(outfilenum) = temp_outfile
exit
case default
print *, "File type: ", trim(temp_outfile(scan(temp_outfile,'.',.true.):)), " not currently accepted. ", &
"please input a filename with extension from following list: xyz, lmp, vtk, cac."
read(*,*) temp_outfile
end select
end do
end subroutine get_out_file
subroutine write_out
!This subroutine loops over alll of the outfile types defined and calls the correct writing subroutine
integer :: i
!Find max esize which will be needed later
call set_max_esize
do i = 1, outfilenum
print *, "Writing data out to ", trim(adjustl(outfiles(i)))
!Pull out the extension of the file and call the correct write subroutine
select case(trim(adjustl(outfiles(i)(scan(outfiles(i),'.',.true.)+1:))))
case('xyz')
call write_xyz(outfiles(i))
case('lmp')
call write_lmp(outfiles(i))
case('vtk')
call write_vtk(outfiles(i))
case('mb')
call write_mb(outfiles(i))
case('restart')
call write_pycac(outfiles(i))
case('cac')
call write_lmpcac(outfiles(i))
case default
print *, "The extension ", trim(adjustl(outfiles(i)(scan(outfiles(i),'.',.true.)+1:))), &
" is not accepted for writing. Please select from: xyz and try again"
stop
end select
end do
end subroutine write_out
subroutine write_xyz(file)
!This is the simplest visualization subroutine, it writes out all nodal positions and atom positions to an xyz file
character(len=100), intent(in) :: file
integer :: i, inod, ibasis
open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
!Write total number of atoms + elements
write(11, '(i16)') node_num+atom_num
!Write comment line
write(11, '(a)') "#Node + atom file created using cacmb"
!Write nodal positions
do i = 1, ele_num
do inod = 1, ng_node(lat_ele(i))
do ibasis = 1, basisnum(lat_ele(i))
write(11, '(i16, 3f23.15)') basis_type(ibasis,lat_ele(i)), r_node(:,ibasis,inod,i)
end do
end do
end do
!Write atom positions
do i = 1, atom_num
write(11, '(i16, 3f23.15)') type_atom(i), r_atom(:,i)
end do
!Finish writing
close(11)
end subroutine write_xyz
subroutine write_lmp(file)
!This subroutine writes out a .lmp style dump file
character(len=100), intent(in) :: file
integer :: write_num, i, iatom, type_interp(max_basisnum*max_esize**3)
real(kind=dp) :: r_interp(3, max_basisnum*max_esize**3), mass
open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
!Comment line
write(11, '(a)') '# lmp file made with cacmb'
write(11, '(a)')
!Calculate total atom number
write_num = atom_num
do i = 1,ele_num
if(type_ele(i) == 'fcc') write_num = write_num + size_ele(i)**3
end do
!Write total number of atoms + elements
write(11, '(i16, a)') write_num, ' atoms'
!Write number of atom types
write(11, '(i16, a)') atom_types, ' atom types'
write(11,'(a)') ' '
!Write box bd
write(11, '(2f23.15, a)') box_bd(1:2), ' xlo xhi'
write(11, '(2f23.15, a)') box_bd(3:4), ' ylo yhi'
write(11, '(2f23.15, a)') box_bd(5:6), ' zlo zhi'
!Masses
write(11, '(a)') 'Masses'
write(11, '(a)') ' '
do i =1, atom_types
call atommass(type_to_name(i),mass)
write(11, '(i16, f23.15)') i, mass
end do
write(11, '(a)') ' '
!Write atom positions
write(11, '(a)') 'Atoms'
write(11, '(a)') ' '
do i = 1, atom_num
write(11, '(2i16, 3f23.15)') i, type_atom(i), r_atom(:,i)
end do
!Write refined element atomic positions
do i = 1, ele_num
call interpolate_atoms(type_ele(i), size_ele(i), lat_ele(i), r_node(:,:,:,i), type_interp, r_interp)
select case(trim(adjustl(type_ele(i))))
case('fcc')
do iatom = 1, basisnum(lat_ele(i))*size_ele(i)**3
call apply_periodic(r_interp(:,iatom))
write(11, '(2i16, 3f23.15)') atom_num+iatom, type_interp(iatom), r_interp(:,iatom)
end do
end select
end do
end subroutine write_lmp
subroutine write_lmpcac(file)
!This subroutine writes out a .lmp style dump file
character(len=100), intent(in) :: file
integer :: write_num, i, inod, ibasis
real(kind=dp) :: mass, fcc_adjust(3,8), local_adjust(3,8), rout(3)
1 format(i16, ' Eight_Node', 4i16)
2 format(i16, ' Atom', 4i16)
3 format(3i16,3f23.15)
open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
!Comment line
write(11, '(a)') '# CAC input file made with cacmb'
write(11, '(a)')
!Calculate total atom number
write_num = atom_num + ele_num
!Write total number of atoms + elements
write(11, '(i16, a)') write_num, ' cac elements'
!Write number of atom types
write(11, '(i16, a)') atom_types, ' atom types'
write(11,'(a)') ' '
!Write box bd
write(11, '(2f23.15, a)') box_bd(1:2), ' xlo xhi'
write(11, '(2f23.15, a)') box_bd(3:4), ' ylo yhi'
write(11, '(2f23.15, a)') box_bd(5:6), ' zlo zhi'
!Masses
write(11, '(a)') 'Masses'
write(11, '(a)') ' '
do i =1, atom_types
call atommass(type_to_name(i),mass)
write(11, '(i16, f23.15, 2a)') i, mass, ' # ', type_to_name(i)
end do
write(11, '(a)') ' '
write(11, '(a)') 'CAC Elements'
write(11, '(a)') ' '
!Set up the nodal adjustment variables for all the different element types. This adjusts the node centers
!from the center of the unit cell (as formulated in this code) to the corners of the unit cells
do inod = 1, 8
do i = 1,3
if(is_equal(cubic_cell(i, inod),0.0_dp)) then
fcc_adjust(i,inod) = -0.5_dp
else
fcc_adjust(i, inod) = 0.5_dp
end if
end do
end do
fcc_adjust = matmul(fcc_mat, fcc_adjust)
!Write element nodal positions
do i = 1, ele_num
select case(trim(adjustl(type_ele(i))))
case('fcc')
!Now orient the current adjustment vector to the correct orientation
local_adjust = matmul(sub_box_ori(:,:,sbox_ele(i)), fcc_adjust) * lapa(lat_ele(i))
!The first entry is the element specifier
write(11,1) i, basisnum(lat_ele(i)), size_ele(i), size_ele(i), size_ele(i)
do ibasis = 1, basisnum(lat_ele(i))
do inod = 1, 8
!Nodal information for every node
rout = r_node(:,ibasis,inod,i) + local_adjust(:,inod)
write(11,3) inod, ibasis, basis_type(ibasis,lat_ele(i)), rout
end do
end do
end select
end do
do i = 1, atom_num
!Element specifier dictating that it is an atom
write(11,2) ele_num+i, 1, 1, 1, 1
!Write the atomic information
write(11,3) 1, 1, type_atom(i), r_atom(:,i)
end do
end subroutine write_lmpcac
subroutine write_vtk(file)
!This subroutine writes out a vtk style dump file
integer :: i, j, inod, ibasis
character(len=100), intent(in) :: file
1 format('# vtk DataFile Version 4.0.1', / &
'CAC output -- cg', / &
'ASCII')
11 format('# vtk DataFile Version 4.0.1', / &
'CACmb output -- atoms', / &
'ASCII')
2 format('DATASET UNSTRUCTURED_GRID')
3 format('POINTS', i16, ' float')
4 format(/'CELLS', 2i16)
5 format(/'CELL_TYPES', i16)
12 format(/'CELL_DATA', i16)
16 format(/'POINT_DATA', i16)
17 format('SCALARS weight float', / &
'LOOKUP_TABLE default')
18 format('SCALARS atom_type float', / &
'LOOKUP_TABLE default')
20 format('SCALARS lattice_type float', /&
'LOOKUP_TABLE default')
21 format('SCALARS esize float', /&
'LOOKUP_TABLE default')
!First we write the vtk file containing the atoms
open(unit=11, file='atoms_'//trim(adjustl(file)), action='write', status='replace',position='rewind')
write(11, 11)
write(11, 2)
write(11, 3) atom_num
do i = 1, atom_num
write(11, '(3f23.15)') r_atom(:,i)
end do
write(11,4) atom_num, atom_num*2
do i = 1, atom_num
write(11, '(2i16)') 1, i-1
end do
write(11, 5) atom_num
do i = 1, atom_num
write(11, '(i16)') 1
end do
write(11, 16) atom_num
write(11, 18)
do i = 1, atom_num
write(11, '(i16)') type_atom(i)
end do
close(11)
open(unit=11, file='cg_'//trim(adjustl(file)), action='write', status='replace',position='rewind')
write(11,1)
write(11,2)
write(11,3) node_num
do i = 1, ele_num
do inod=1, ng_node(lat_ele(i))
do ibasis = 1, basisnum(lat_ele(i))
write(11, '(3f23.15)') sum(r_node(:,:,inod,i),2)/basisnum(lat_ele(i))
end do
end do
end do
write(11, 4) ele_num, ele_num + node_num
do i =1, ele_num
write(11, '(9i16)') ng_node(lat_ele(i)), (j, j = (i-1)*ng_node(lat_ele(i)), i*ng_node(lat_ele(i))-1)
end do
write(11,5) ele_num
do i = 1, ele_num
if(trim(adjustl(type_ele(i))) == 'fcc') write(11, '(i16)') 12
end do
write(11,12) ele_num
write(11,20)
do i = 1, ele_num
write(11, '(i16)') lat_ele(i)
end do
write(11,21)
do i = 1, ele_num
write(11, '(i16)') size_ele(i)
end do
close(11)
end subroutine
subroutine write_pycac(file)
!This subroutine writes restart files meant to be used with the McDowell Group CAC code.
!NOTE: This code doesn't work for arbitrary number of basis atoms per node. It assumes that the
!each element has only 1 atom type at the node.
character(len=100), intent(in) :: file
integer :: interp_max, i, j, inod, ibasis, ip, unique_index(10), unique_num
real(kind=dp) :: box_vec(3)
1 format('time' / i16, f23.15)
2 format('number of elements' / i16)
3 format('number of nodes' / i16)
4 format('element types' / i16)
5 format('number of atoms' / i16)
6 format('number of grains' / i16)
7 format('boundary ' / 3a1)
8 format('box bound' / 6f23.15)
9 format('box length' / 3f23.15)
10 format('box matrix')
11 format(3f23.15)
12 format('coarse-grained domain')
13 format('ie ele_type grain_ele lat_type_ele'/ 'ip ibasis type x y z')
14 format('atomistic domain' / 'ia grain_atom type_atom x y z')
15 format('maximum lattice periodicity length' / 3f23.15)
16 format('Number of lattice types and atom types '/ 2i16)
17 format('lattice type IDs')
18 format('lattice types for grains')
19 format('max nodes per element' / i16)
20 format('max interpo per element' / i16)
21 format('atom types to elements')
open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
write(11,1) timestep, total_time
write(11,2) ele_num
!Below writes the header information for the restart file
!Calculate the max number of atoms per element
select case(max_ng_node)
case(8)
interp_max = (max_esize)**3
case default
interp_max = 0
end select
write(11,20) interp_max
write(11,3) node_num
write(11,19) max_ng_node
write(11,4) lattice_types
write(11,5) atom_num
write(11,6) 1 !Grain_num is ignored
write(11,16) lattice_types, atom_types
write(11,21)
do i = 1, atom_types
write(11,*) i, type_to_name(i)
end do
write(11,7) box_bc(1:1), box_bc(2:2), box_bc(3:3)
write(11,18)
write(11,'(2i16)') 1,1 !This is another throwaway line that is meaningless
write(11,17)
!This may have to be updated in the future but currently the only 8 node element is fcc
do i = 1, lattice_types
select case(ng_node(i))
case(8)
write(11, *) i, 'fcc'
end select
end do
write(11,15) 1.0_dp, 1.0_dp, 1.0_dp !Another throwaway line that isn't needed
write(11,8) box_bd
write(11,9) box_bd(2)-box_bd(1), box_bd(4) - box_bd(3), box_bd(6)-box_bd(5)
write(11,10)
!Current boxes are limited to being rectangular
do i = 1,3
box_vec(:) = 0.0_dp
box_vec(i) = box_bd(2*i) - box_bd(2*i-1)
write(11,11) box_vec
end do
!We write this as box_mat ori and box_mat current
do i = 1,3
box_vec(:) = 0.0_dp
box_vec(i) = box_bd(2*i) - box_bd(2*i-1)
write(11,11) box_vec
end do
!write the element information
if(ele_num > 0) then
write(11,12)
!First figure out all of the unique element types
unique_num = 0
unique_index(:) = 0
eleloop:do i = 1, ele_num
do j =1 , unique_num
if ( ( size_ele(i) == size_ele( unique_index(j) ) ).and. &
( lat_ele(i) == lat_ele(unique_index(j)) ) ) then
cycle eleloop
end if
end do
unique_num = unique_num + 1
unique_index(unique_num) = i
end do eleloop
do i = 1, unique_num
write(11,'(3i16)') i, size_ele(i)-1, basis_type(1,i)
end do
ip = 0
write(11,13)
do i = 1, ele_num
write(11, '(4i16)') i, lat_ele(i), 1, basis_type(1,lat_ele(i))
do inod = 1, ng_node(lat_ele(i))
do ibasis = 1, basisnum(lat_ele(i))
ip = ip + 1
write(11, '(2i16, 3f23.15)') ip, ibasis, r_node(:, ibasis, inod, i)
end do
end do
end do
end if
!Now write the atomic information
if(atom_num /= 0) then
write(11,14)
do i = 1, atom_num
write(11, '(3i16, 3f23.15)') i, 1, type_atom(i), r_atom(:,i)
end do
end if
close(11)
end subroutine write_pycac
subroutine write_mb(file)
!This subroutine writes the cacmb formatted file which provides necessary information for building models
character(len=100), intent(in) :: file
integer :: i, j, k, inod, ibasis
!Open the .mb file for writing
open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
!First write the box boundary information
!Write the global box boundaries
write(11,*) box_bd(:)
!Write the number of sub_boxes in the system
write(11,*) sub_box_num
!For every subbox write the orientation, sub box boundary, and sub_box_array_bds
do i = 1, sub_box_num
write(11,*) sub_box_ori(:,:,i)
write(11,*) sub_box_bd(:,i)
write(11,*) ((sub_box_array_bd(j,k,i), j = 1, 2), k = 1, 2)
end do
!Write the number of atom types in the current model and all of their names
write(11,*) atom_types, (type_to_name(i)//' ', i=1, atom_types)
!Write the number of lattice_types, basisnum and number of nodes for each lattice type
write(11,*) lattice_types, (basisnum(i), i = 1, lattice_types), (ng_node(i), i = 1, lattice_types)
!Now for every lattice type write the basis atom types
write(11,*) ((basis_type(i,j), i = 1, basisnum(j)), j = 1, lattice_types)
!Now for every lattice type write the lattice parameters
write(11,*) (lapa(i), i = 1, lattice_types)
!Now write the numbers of elements and atoms
write(11,*) atom_num, ele_num
!Write out atoms first
do i = 1, atom_num
write(11,*) i, type_atom(i), sbox_atom(i), r_atom(:,i)
end do
!Write out the elements, this is written in two stages, one line for the element and then 1 line for
!every basis at every node
do i = 1, ele_num
write(11, *) i, lat_ele(i), size_ele(i), sbox_ele(i), type_ele(i)
do inod = 1, ng_node(lat_ele(i))
do ibasis =1, basisnum(lat_ele(i))
write(11,*) inod, ibasis, r_node(:, ibasis, inod, i)
end do
end do
end do
close(11)
end subroutine write_mb
!!!!!!!!!!!!! Below are subroutines for reading files !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
subroutine get_in_file(filename)
implicit none
character(len=100), intent(in) :: filename
character(len=100) :: temp_infile
logical :: file_exists
!If no filename is provided then this function is called with none and prompts user input
if (filename=='none') then
print *, "Please specify a filename or extension to output to:"
read(*,*) temp_infile
else
temp_infile = filename
end if
!Infinite loop which only exists if user provides valid filetype
do while(.true.)
!Check to see if file exists, if it does then ask user if they would like to overwrite the file
inquire(file=trim(temp_infile), exist=file_exists)
if (.not.file_exists) then
print *, "The file ", trim(adjustl(filename)), " does not exist. Please input a filename that exists"
read(*,*) temp_infile
cycle
end if
select case(temp_infile(scan(temp_infile,'.',.true.)+1:))
case('xyz', 'lmp', 'vtk', 'mb')
infilenum=infilenum+1
infiles(infilenum) = temp_infile
exit
case default
print *, "File type: ", trim(temp_infile(scan(temp_infile,'.',.true.):)), "not currently accepted. ", &
"please input a filename with extension from following list: mb."
read(*,*) temp_infile
end select
end do
end subroutine get_in_file
subroutine read_in(i, displace, temp_box_bd)
!This subroutine loops over alll of the outfile types defined and calls the correct writing subroutine
integer, intent(in) :: i
real(kind=dp), dimension(3), intent(in) :: displace
real(kind=dp), dimension(6), intent(out) :: temp_box_bd
!Pull out the extension of the file and call the correct write subroutine
select case(trim(adjustl(infiles(i)(scan(infiles(i),'.',.true.)+1:))))
case('mb')
call read_mb(infiles(i), displace, temp_box_bd)
case default
print *, "The extension ", trim(adjustl(outfiles(i)(scan(outfiles(i),'.',.true.)+1:))), &
" is not accepted for writing. Please select from: mb and try again"
stop
end select
end subroutine read_in
subroutine read_mb(file, displace, temp_box_bd)
!This subroutine reads in an mb file for operation
character(len=100), intent(in) :: file
real(kind=dp), dimension(3), intent(in) :: displace
real(kind = dp), dimension(6), intent(out) :: temp_box_bd
integer :: i, j, k, l, n, inod, ibasis, type, size, in_atoms, in_eles, new_atom_types, &
new_type_to_type(10), new_lattice_types, sbox, new_lattice_map(10)
character(len=100) :: etype
real(kind=dp) :: r(3), newdisplace(3)
real(kind=dp), allocatable :: r_innode(:,:,:)
character(len = 2) :: new_type_to_name(10)
!First open the file
open(unit=11, file=trim(adjustl(file)), action='read',position='rewind')
!Read in the box boundary and grow the current active box bd
read(11, *) temp_box_bd(:)
print *, "displace", displace
do i = 1, 3
if (displace(i) > lim_zero) then
newdisplace(i) = displace(i) - temp_box_bd(2*i-1)
else
newdisplace=displace(i)
end if
temp_box_bd(2*i-1) = temp_box_bd(2*i-1) + newdisplace(i)
temp_box_bd(2*i) = temp_box_bd(2*i) + newdisplace(i)
end do
call grow_box(temp_box_bd)
!Read in the number of sub_boxes and allocate the variables
read(11, *) n
if (sub_box_num == 0) then
call alloc_sub_box(n)
else
call grow_sub_box(n)
end if
!Read in subbox orientations and boundaries
do i = 1, n
!Read in orientation with column major ordering
read(11,*) ((sub_box_ori(j, k, sub_box_num+i), j = 1, 3), k = 1, 3)
!Read in subbox boundaries
read(11,*) sub_box_bd(:,sub_box_num+i)
do j = 1, 3
sub_box_bd(2*j-1,sub_box_num+i) = sub_box_bd(2*j-1, sub_box_num+i) + displace(j)
sub_box_bd(2*j,sub_box_num+i) = sub_box_bd(2*j, sub_box_num+i) + displace(j)
end do
!Read in sub_box_array_bd
read(11,*) ((sub_box_array_bd(j, k, sub_box_num+i), j = 1, 2), k = 1, 2)
end do
!Add the existing element boundaries
sub_box_array_bd(:,1,sub_box_num+1:) = sub_box_array_bd(:,1,sub_box_num+1:) + atom_num
sub_box_array_bd(:,2,sub_box_num+1:) = sub_box_array_bd(:,2,sub_box_num+1:) + ele_num
!Read in the number of atom types and all their names
read(11, *) new_atom_types, (new_type_to_name(i), i = 1, new_atom_types)
!Now fit these into the global list of atom types, after this new_type_to_type is the actual global
!type of the atoms within this file
do i = 1, new_atom_types
call add_atom_type(new_type_to_name(i), new_type_to_type(i))
end do
!Read the number of lattice types, basisnum, and number of nodes for each lattice type
read(11,*) new_lattice_types, (basisnum(i), i = lattice_types+1, lattice_types+new_lattice_types), &
(ng_node(i), i = lattice_types+1, lattice_types+new_lattice_types)
!Define max_ng_node and max_basis_num
max_basisnum = maxval(basisnum)
max_ng_node = maxval(ng_node)
!Read the basis atom types for every lattice
read(11,*) ((basis_type(i,j), i = 1, basisnum(j)), j = lattice_types+1, lattice_types+new_lattice_types)
!Convert the basis_atom types
do j = lattice_types+1, lattice_types+new_lattice_types
do i = 1, basisnum(j)
basis_type(i,j) = new_type_to_type(basis_type(i,j))
end do
end do
!Read the lattice parameters for every lattice type
read(11,*) (lapa(i), i = lattice_types+1, lattice_types+new_lattice_types)
!Now we loop over all new lattice types and check to see if they are exactly the same as any old lattice types
!If they are then we map the new type to the old type.
k = lattice_types + 1
new_lattice_map(:) = 0
new_loop:do i = 1, new_lattice_types
old_loop:do j = 1, lattice_types
!First check all the lattice level variables
if ((basisnum(i) == basisnum(j)).and. &
(ng_node(i) == ng_node(j))) then
!Now check the basis level variables
do ibasis =1, basisnum(i)
if(basis_type(ibasis,lattice_types+i) /= basis_type(ibasis,j)) then
cycle old_loop
end if
end do
new_lattice_map(i) = j
cycle new_loop
end if
end do old_loop
new_lattice_map(i) = k
k = k+1
end do new_loop
!Read number of elements and atoms and allocate arrays
read(11, *) in_atoms, in_eles
call grow_ele_arrays(in_eles, in_atoms)
allocate(r_innode(3,max_basisnum, max_ng_node))
print *, "Read in ", in_eles, " elements and ", in_atoms, " atoms from ", trim(adjustl(file))
print *, "New box dimensions are: ", box_bd
!Read the atoms
do i = 1, in_atoms
read(11,*) j, type, sbox, r(:)
r = r+newdisplace
call add_atom(new_type_to_type(type), sbox+sub_box_num, r)
end do
!Read the elements
do i = 1, in_eles
read(11, *) l, type, size, sbox, etype
do inod = 1, ng_node(type)
do ibasis =1, basisnum(type)
read(11,*) j, k, r_innode(:, ibasis, inod)
r_innode(:,ibasis,inod) = r_innode(:, ibasis, inod) + newdisplace
end do
end do
call add_element(etype, size, new_lattice_map(type), sbox+sub_box_num, r_innode)
end do
!Close the file being read
close(11)
!Only increment the lattice types if there are elements, if there are no elements then we
!just overwrite the arrays
lattice_types = maxval(new_lattice_map)
sub_box_num = sub_box_num + n
call set_max_esize
end subroutine read_mb
end module io