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724 lines
26 KiB
724 lines
26 KiB
module io
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use elements
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use parameters
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use atoms
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use box
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implicit none
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integer :: outfilenum = 0, infilenum = 0
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character(len=100) :: outfiles(10), infiles(10)
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logical lmpcac
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public
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contains
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! Subroutines for writing out data files !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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subroutine get_out_file(filename)
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implicit none
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character(len=100), intent(in) :: filename
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character(len=100) :: temp_outfile
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character(len=1) :: overwrite
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logical :: file_exists
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!If no filename is provided then this function is called with none and prompts user input
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if (filename=='none') then
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print *, "Please specify a filename or extension to output to:"
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read(*,*) temp_outfile
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else
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temp_outfile = filename
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end if
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!Infinite loop which only exists if user provides valid filetype
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overwrite = 'r'
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do while(.true.)
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!Check to see if file exists, if it does then ask user if they would like to overwrite the file
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inquire(file=trim(temp_outfile), exist=file_exists)
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if (file_exists) then
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if (overwrite == 'r') print *, "File ", trim(temp_outfile), " already exists. Would you like to overwrite? (Y/N)"
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read(*,*) overwrite
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if((scan(overwrite, "n") > 0).or.(scan(overwrite, "N") > 0)) then
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print *, "Please specify a new filename with extension:"
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read(*,*) temp_outfile
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else if((scan(overwrite, "y") > 0).or.(scan(overwrite, "Y") > 0)) then
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continue
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else
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print *, "Please pick either y or n"
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read(*,*) overwrite
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end if
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end if
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if (scan(temp_outfile,'.',.true.) == 0) then
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print *, "No extension included on filename, please type a full filename that includes an extension."
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read(*,*) temp_outfile
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cycle
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end if
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select case(temp_outfile(scan(temp_outfile,'.',.true.)+1:))
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case('xyz', 'lmp', 'vtk', 'mb', 'restart')
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outfilenum=outfilenum+1
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outfiles(outfilenum) = temp_outfile
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exit
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case('cac')
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lmpcac = .true.
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outfilenum=outfilenum+1
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outfiles(outfilenum) = temp_outfile
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exit
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case default
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print *, "File type: ", trim(temp_outfile(scan(temp_outfile,'.',.true.):)), " not currently accepted. ", &
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"please input a filename with extension from following list: xyz, lmp, vtk, cac."
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read(*,*) temp_outfile
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end select
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end do
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end subroutine get_out_file
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subroutine get_in_file(filename)
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implicit none
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character(len=100), intent(in) :: filename
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character(len=100) :: temp_infile
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logical :: file_exists
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!If no filename is provided then this function is called with none and prompts user input
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if (filename=='none') then
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print *, "Please specify a filename with extension to read in:"
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read(*,*) temp_infile
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else
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temp_infile = filename
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end if
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!Infinite loop which only exists if user provides valid filetype
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do while(.true.)
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!Check to see if file exists, if it doesn't then ask the user for another input
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inquire(file=trim(temp_infile), exist=file_exists)
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if (.not.file_exists) then
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print *, "The file ", temp_infile, "does not exist, please input an existing file to read in."
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read(*,*) temp_infile
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cycle
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end if
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if (scan(temp_infile,'.',.true.) == 0) then
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print *, "No extension included on filename, please type a full filename that includes an extension."
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read(*,*) temp_infile
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cycle
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end if
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select case(temp_infile(scan(temp_infile,'.',.true.)+1:))
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case('cac')
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infilenum=infilenum+1
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infiles(infilenum) = temp_infile
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exit
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case default
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print *, "File type: ", trim(temp_infile(scan(temp_infile,'.',.true.):)), " not currently accepted. ", &
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"please input a filename with extension from following list: cac."
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read(*,*) temp_infile
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end select
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end do
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end subroutine get_in_file
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subroutine write_out
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!This subroutine loops over alll of the outfile types defined and calls the correct writing subroutine
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integer :: i
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!Find max esize which will be needed later
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call set_max_esize
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do i = 1, outfilenum
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!Pull out the extension of the file and call the correct write subroutine
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select case(trim(adjustl(outfiles(i)(scan(outfiles(i),'.',.true.)+1:))))
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case('xyz')
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call write_xyz(outfiles(i))
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case('lmp')
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call write_lmp(outfiles(i))
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case('vtk')
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call write_vtk(outfiles(i))
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case('mb')
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call write_mb(outfiles(i))
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case('restart')
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call write_pycac(outfiles(i))
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case('cac')
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call write_lmpcac(outfiles(i))
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case default
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print *, "The extension ", trim(adjustl(outfiles(i)(scan(outfiles(i),'.',.true.)+1:))), &
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" is not accepted for writing. Please select from: xyz and try again"
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stop
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end select
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end do
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end subroutine write_out
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subroutine write_xyz(file)
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!This is the simplest visualization subroutine, it writes out all nodal positions and atom positions to an xyz file
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character(len=100), intent(in) :: file
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integer :: i, inod, ibasis
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open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
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!Write total number of atoms + elements
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write(11, '(i16)') node_num+atom_num
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!Write comment line
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write(11, '(a)') "#Node + atom file created using cacmb"
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!Write nodal positions
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do i = 1, ele_num
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do inod = 1, ng_node(lat_ele(i))
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do ibasis = 1, basisnum(lat_ele(i))
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write(11, '(a, 3f23.15)') basis_type(ibasis,lat_ele(i)), r_node(:,ibasis,inod,i)
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end do
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end do
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end do
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!Write atom positions
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do i = 1, atom_num
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write(11, '(a, 3f23.15)') type_atom(i), r_atom(:,i)
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end do
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!Finish writing
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close(11)
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end subroutine write_xyz
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subroutine write_lmp(file)
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!This subroutine writes out a .lmp style dump file
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character(len=100), intent(in) :: file
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integer :: write_num, i, iatom, type_interp(max_basisnum*max_esize**3)
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real(kind=dp) :: r_interp(3, max_basisnum*max_esize**3), mass
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open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
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!Comment line
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write(11, '(a)') '# lmp file made with cacmb'
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write(11, '(a)')
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!Calculate total atom number
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write_num = atom_num
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do i = 1,ele_num
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if(type_ele(i) == 'fcc') write_num = write_num + size_ele(i)**3
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end do
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!Write total number of atoms + elements
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write(11, '(i16, a)') write_num, ' atoms'
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!Write number of atom types
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write(11, '(i16, a)') atom_types, ' atom types'
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write(11,'(a)') ' '
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!Write box bd
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write(11, '(2f23.15, a)') box_bd(1:2), ' xlo xhi'
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write(11, '(2f23.15, a)') box_bd(3:4), ' ylo yhi'
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write(11, '(2f23.15, a)') box_bd(5:6), ' zlo zhi'
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!Masses
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write(11, '(a)') 'Masses'
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write(11, '(a)') ' '
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do i =1, atom_types
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call atommass(type_to_name(i),mass)
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write(11, '(i16, f23.15)') i, mass
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end do
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write(11, '(a)') ' '
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!Write atom positions
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write(11, '(a)') 'Atoms'
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write(11, '(a)') ' '
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do i = 1, atom_num
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write(11, '(2i16, 3f23.15)') i, type_atom(i), r_atom(:,i)
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end do
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!Write refined element atomic positions
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do i = 1, ele_num
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call interpolate_atoms(type_ele(i), size_ele(i), lat_ele(i), r_node(:,:,:,i), type_interp, r_interp)
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select case(trim(adjustl(type_ele(i))))
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case('fcc')
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do iatom = 1, basisnum(lat_ele(i))*size_ele(i)**3
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write(11, '(2i16, 3f23.15)') atom_num+iatom, type_interp(iatom), r_interp(:,iatom)
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end do
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end select
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end do
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end subroutine write_lmp
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subroutine write_lmpcac(file)
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!This subroutine writes out a .lmp style dump file
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character(len=100), intent(in) :: file
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integer :: write_num, i, inod, ibasis
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real(kind=dp) :: mass
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1 format(i16, ' Eight_Node', 4i16)
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2 format(i16, ' Atom', 4i16)
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3 format(3i16,3f23.15)
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open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
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!Comment line
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write(11, '(a)') '# CAC input file made with cacmb'
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write(11, '(a)')
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!Calculate total atom number
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write_num = atom_num + ele_num
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!Write total number of atoms + elements
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write(11, '(i16, a)') write_num, ' cac elements'
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!Write number of atom types
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write(11, '(i16, a)') atom_types, ' atom types'
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write(11,'(a)') ' '
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!Write box bd
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write(11, '(2f23.15, a)') box_bd(1:2), ' xlo xhi'
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write(11, '(2f23.15, a)') box_bd(3:4), ' ylo yhi'
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write(11, '(2f23.15, a)') box_bd(5:6), ' zlo zhi'
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!Masses
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write(11, '(a)') 'Masses'
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write(11, '(a)') ' '
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do i =1, atom_types
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call atommass(type_to_name(i),mass)
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write(11, '(i16, f23.15, 2a)') i, mass, ' # ', type_to_name(i)
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end do
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write(11, '(a)') ' '
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write(11, '(a)') 'CAC Elements'
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write(11, '(a)') ' '
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!Write element nodal positions
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do i = 1, ele_num
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select case(trim(adjustl(type_ele(i))))
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case('fcc')
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!The first entry is the element specifier
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write(11,1) i, basisnum(lat_ele(i)), size_ele(i), size_ele(i), size_ele(i)
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do ibasis = 1, basisnum(lat_ele(i))
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do inod = 1, 8
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!Nodal information for every node
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write(11,3) inod, ibasis, basis_type(ibasis,lat_ele(i)), r_node(:,ibasis,inod,i)
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end do
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end do
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end select
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end do
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do i = 1, atom_num
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!Element specifier dictating that it is an atom
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write(11,2) ele_num+i, 1, 1, 1, 1
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!Write the atomic information
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write(11,3) 1, 1, type_atom(i), r_atom(:,i)
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end do
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end subroutine write_lmpcac
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subroutine write_vtk(file)
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!This subroutine writes out a vtk style dump file
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integer :: i, j, inod, ibasis
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character(len=100), intent(in) :: file
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1 format('# vtk DataFile Version 4.0.1', / &
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'CAC output -- cg', / &
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'ASCII')
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11 format('# vtk DataFile Version 4.0.1', / &
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'CACmb output -- atoms', / &
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'ASCII')
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2 format('DATASET UNSTRUCTURED_GRID')
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3 format('POINTS', i16, ' float')
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4 format(/'CELLS', 2i16)
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5 format(/'CELL_TYPES', i16)
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12 format(/'CELL_DATA', i16)
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16 format(/'POINT_DATA', i16)
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17 format('SCALARS weight float', / &
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'LOOKUP_TABLE default')
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18 format('SCALARS atom_type float', / &
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'LOOKUP_TABLE default')
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20 format('SCALARS lattice_type float', /&
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'LOOKUP_TABLE default')
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!First we write the vtk file containing the atoms
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open(unit=11, file='atoms_'//trim(adjustl(file)), action='write', status='replace',position='rewind')
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write(11, 11)
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write(11, 2)
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write(11, 3) atom_num
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do i = 1, atom_num
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write(11, '(3f23.15)') r_atom(:,i)
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end do
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write(11,4) atom_num, atom_num*2
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do i = 1, atom_num
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write(11, '(2i16)') 1, i-1
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end do
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write(11, 5) atom_num
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do i = 1, atom_num
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write(11, '(i16)') 1
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end do
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write(11, 16) atom_num
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write(11, 18)
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do i = 1, atom_num
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write(11, '(i16)') type_atom(i)
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end do
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close(11)
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open(unit=11, file='cg_'//trim(adjustl(file)), action='write', status='replace',position='rewind')
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write(11,1)
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write(11,2)
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write(11,3) node_num
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do i = 1, ele_num
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do inod=1, ng_node(lat_ele(i))
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do ibasis = 1, basisnum(lat_ele(i))
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write(11, '(3f23.15)') sum(r_node(:,:,inod,i),2)/basisnum(lat_ele(i))
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end do
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end do
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end do
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write(11, 4) ele_num, ele_num + node_num
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do i =1, ele_num
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write(11, '(9i16)') ng_node(lat_ele(i)), (j, j = (i-1)*ng_node(lat_ele(i)), i*ng_node(lat_ele(i))-1)
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end do
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write(11,5) ele_num
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do i = 1, ele_num
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if(trim(adjustl(type_ele(i))) == 'fcc') write(11, '(i16)') 12
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end do
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write(11,12) ele_num
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write(11,20)
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do i = 1, ele_num
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write(11, '(i16)') lat_ele(i)
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end do
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close(11)
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end subroutine
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subroutine write_pycac(file)
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!This subroutine writes restart files meant to be used with the McDowell Group CAC code.
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!NOTE: This code doesn't work for arbitrary number of basis atoms per node. It assumes that the
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!each element has only 1 atom type at the node.
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character(len=100), intent(in) :: file
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integer :: interp_max, i, j, lat_size, inod, ibasis, ip
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real(kind=dp) :: box_vec(3)
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1 format('time' / i16, f23.15)
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2 format('number of elements' / i16)
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3 format('number of nodes' / i16)
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4 format('element types' / i16)
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5 format('number of atoms' / i16)
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6 format('number of grains' / i16)
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7 format('boundary ' / 3a1)
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8 format('box bound' / 6f23.15)
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9 format('box length' / 3f23.15)
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10 format('box matrix')
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11 format(3f23.15)
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12 format('coarse-grained domain')
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13 format('ie ele_type grain_ele lat_type_ele'/ 'ip ibasis type x y z')
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14 format('atomistic domain' / 'ia grain_atom type_atom x y z')
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15 format('maximum lattice periodicity length' / 3f23.15)
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16 format('Number of lattice types and atom types '/ 2i16)
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17 format('lattice type IDs')
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18 format('lattice types for grains')
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19 format('max nodes per element' / i16)
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20 format('max interpo per element' / i16)
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21 format('atom types to elements')
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open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind')
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write(11,1) timestep, total_time
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write(11,2) ele_num
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!Below writes the header information for the restart file
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!Calculate the max number of atoms per element
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select case(max_ng_node)
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case(8)
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interp_max = (max_esize)**3
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end select
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write(11,20) interp_max
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write(11,3) node_num
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write(11,19) max_ng_node
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write(11,4) lattice_types
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write(11,2) atom_num
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write(11,6) 1 !Grain_num is ignored
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write(11,16) lattice_types, atom_types
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write(11,21)
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do i = 1, atom_types
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write(11,*) i, type_to_name(i)
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end do
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write(11,7) box_bc(1:1), box_bc(2:2), box_bc(3:3)
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write(11,18)
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write(11,'(2i16)') 1,1 !This is another throwaway line that is meaningless
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write(11,17)
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!This may have to be updated in the future but currently the only 8 node element is fcc
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do i = 1, lattice_types
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select case(ng_node(i))
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case(8)
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write(11, *) i, 'fcc'
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end select
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end do
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write(11,15) 1.0_dp, 1.0_dp, 1.0_dp !Another throwaway line that isn't needed
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write(11,8) box_bd
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write(11,9) box_bd(2)-box_bd(1), box_bd(4) - box_bd(3), box_bd(6)-box_bd(5)
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write(11,10)
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!Current boxes are limited to being rectangular
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do i = 1,3
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box_vec(:) = 0.0_dp
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box_vec(i) = box_bd(2*i) - box_bd(2*i-1)
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write(11,11) box_vec
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end do
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!We write this as box_mat ori and box_mat current
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do i = 1,3
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box_vec(:) = 0.0_dp
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box_vec(i) = box_bd(2*i) - box_bd(2*i-1)
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write(11,11) box_vec
|
|
end do
|
|
|
|
!write the element information
|
|
if(ele_num > 0) then
|
|
write(11,12)
|
|
do i = 1, lattice_types
|
|
do j = 1, ele_num
|
|
if (lat_ele(j) == i) then
|
|
lat_size = size_ele(j)-1
|
|
exit
|
|
end if
|
|
end do
|
|
write(11,'(3i16)') i, lat_size, 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 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), 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), 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, n, inod, ibasis, type, size, in_atoms, in_eles, new_atom_types, &
|
|
new_type_to_type(10), new_lattice_types
|
|
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(:)
|
|
|
|
do i = 1, 3
|
|
newdisplace(i) = displace(i) - temp_box_bd(2*i-1)
|
|
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
|
|
|
|
!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)
|
|
sub_box_bd(:,sub_box_num+i) = sub_box_bd(:, sub_box_num+i) + displace(:)
|
|
!Read in sub_box_array_bd
|
|
read(11,*) ((sub_box_ori(j, k, sub_box_num+i), j = 1, 2), k = 1, 2)
|
|
|
|
end do
|
|
sub_box_num = sub_box_num + n
|
|
|
|
!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 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))
|
|
|
|
!Read the atoms
|
|
do i = 1, in_atoms
|
|
read(11,*) j, type, r(:)
|
|
call add_atom(new_type_to_type(type), r+newdisplace)
|
|
end do
|
|
|
|
!Read the elements
|
|
do i = 1, in_eles
|
|
read(11, *) n, type, size, 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
|
|
type = type + lattice_types
|
|
call add_element(etype, size, type, 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
|
|
if(in_eles > 0) lattice_types = lattice_types + new_lattice_types
|
|
end subroutine read_mb
|
|
end module io
|