diff --git a/README.md b/README.md index d390177..cf7fcfb 100644 --- a/README.md +++ b/README.md @@ -111,4 +111,46 @@ This mode merges multiple data files and creates one big simulation cell. The pa `N` - The number of files which are being read -`dim` - the dimension they are to be stacked along, can be either `x`, `y`, or `z`. If the argument `none` is passed then the cells are just overlaid. Future options will include a delete overlap command. \ No newline at end of file +`dim` - the dimension they are to be stacked along, can be either `x`, `y`, or `z`. If the argument `none` is passed then the cells are just overlaid. Future options will include a delete overlap command. + +## Options + +Options are additional portions of code which have additional functionality. Options are performed in the order that they appear in the argument list and can be added to any mode. If wanting to use strictly options use `--convert` to specify input and output files. + +### Option dislgen + +``` +-dislgen [ijk] [hkl] x y z char_angle poisson +``` + + + +This options adds an arbitrarily oriented dislocation into your model based on user inputs using the volterra displacement fields. The options are below + +`[ijk]` - The vector for the line direction + +`[hkl]` - The vector for the slip plane + +`x y z` - The position of the dislocation centroid + +`char_angle` - Character angle of the dislocation (0 is screw and 90 is edge) + +`poisson` - Poisson's ratio used for the displacement field. + +### Option disloop + +```` +-disloop loop_normal radius x y z bx by bz poisson +```` + +This option deletes vacancies on a plane which when minimized should result in a dislocation loop structure. The arguments are below: + +`dim` - The box dimension which defines the normal to the loop plane. As of now this dimension must be a closed back direction, meaning that for fcc a box dimension has to be of the (111) family of planes. Either `x`, `y`, or `z`. + +`n` - The number of atoms to delete on the loop plane + +`x y z` - The centroid of the loop. + +`bx by bz` - The burgers vector for the dislocation + +`poisson` - Poisson ratio for continuum solution \ No newline at end of file diff --git a/src/Makefile b/src/Makefile index 22c84eb..0cdd008 100644 --- a/src/Makefile +++ b/src/Makefile @@ -1,14 +1,15 @@ FC=ifort FFLAGS=-mcmodel=large -g -O0 -stand f08 -fpe0 -traceback -check bounds,uninit -warn all -implicitnone -no-wrap-margin -#FFLAGS=-c -mcmodel=large -Ofast +#FFLAGS=-mcmodel=large -Ofast -no-wrap-margin MODES=mode_create.o mode_merge.o mode_convert.o -OBJECTS=main.o elements.o io.o subroutines.o functions.o atoms.o call_mode.o box.o $(MODES) +OPTIONS=opt_disl.o +OBJECTS=main.o elements.o io.o subroutines.o functions.o atoms.o call_mode.o box.o call_option.o $(MODES) $(OPTIONS) .SUFFIXES: .SUFFIXES: .c .f .f90 .F90 .o cacmb: $(OBJECTS) - $(FC) $(FFLAGS) $(OBJECTS) -o $@ + $(FC) $(FFLAGS) $(OBJECTS) parameters.o -o $@ .f90.o: $(FC) $(FFLAGS) -c $< @@ -18,16 +19,25 @@ clean: $(RM) cacmb *.o testfuncs: testfuncs.o functions.o subroutines.o - $(FC) testfuncs.o functions.o subroutines.o elements.o -o $@ + $(FC) testfuncs.o functions.o subroutines.o box.o elements.o -o $@ .PHONY: cleantest cleantest: $(RM) testfuncs testfuncs.o +.PHONY: test +test: testfuncs + ./testfuncs + +.PHONY: install +install: cacmb + cp ./cacmb /usr/local/bin + $(OBJECTS) : parameters.o -atoms.o subroutines.o testfuncs.o : functions.o -main.o io.o build_subroutines.o: elements.o +atoms.o subroutines.o testfuncs.o box.o : functions.o +main.o io.o $(MODES) $(OPTIONS) : elements.o call_mode.o : $(MODES) +call_option.o : $(OPTIONS) $(MODES) io.o: atoms.o box.o $(MODES) main.o : io.o -testfuncs.o elements.o mode_create.o: subroutines.o +testfuncs.o elements.o mode_create.o opt_disl.o: subroutines.o diff --git a/src/box.f90 b/src/box.f90 index ad5fe55..de8ef59 100644 --- a/src/box.f90 +++ b/src/box.f90 @@ -1,11 +1,11 @@ module box !This module contains information on the properties of the current box. use parameters - + use functions implicit none real(kind=dp) :: box_bd(6) !Global box boundaries - + character(len=3) :: box_bc !Box boundary conditions (periodic or shrinkwrapped) !The subbox variables contain values for each subbox, being the boxes read in through some !command. Currently only mode_merge will require sub_boxes, for mode_create it will always !allocate to only 1 sub_box @@ -14,12 +14,19 @@ module box real(kind=dp), allocatable :: sub_box_ori(:,:,:)!Orientations for each of the subboxes real(kind=dp), allocatable :: sub_box_bd(:,:)!Boundaries for each of the sub_boxes + + !Below are some simulation parameters which may be adjusted if reading in restart files + integer :: timestep=0 + real(kind=dp) :: total_time=0.0_dp + + public contains subroutine box_init !Initialize some box functions box_bd(:) = 0.0_dp + box_bc = 'ppp' end subroutine box_init subroutine alloc_sub_box(n) @@ -27,8 +34,14 @@ module box integer, intent(in) :: n - allocate(sub_box_ori(3,3,n), sub_box_bd(6,n), sub_box_array_bd(2,2,n)) + integer :: i + allocate(sub_box_ori(3,3,n), sub_box_bd(6,n), sub_box_array_bd(2,2,n)) + do i = 1, n + sub_box_ori(:,:,i) = identity_mat(3) + sub_box_bd(:,i) = 0.0_dp + sub_box_array_bd(:,:,i) = 1 + end do end subroutine alloc_sub_box subroutine grow_sub_box(n) @@ -51,7 +64,7 @@ module box call move_alloc(temp_bd, sub_box_bd) temp_array_bd(:,:,1:sub_box_num) = sub_box_array_bd - temp_array_bd(:,:,sub_box_num+1:) = 0.0_dp + temp_array_bd(:,:,sub_box_num+1:) = 1 call move_alloc(temp_array_bd, sub_box_array_bd) return @@ -72,4 +85,21 @@ module box return end subroutine grow_box + + subroutine in_sub_box(r, which_sub_box) + !This returns which sub_box a point is in. It returns the first sub_box with boundaries which + !contain the point. + real(kind=dp), dimension(3), intent(in) :: r + integer, intent(out) :: which_sub_box + + integer :: i + + do i = 1, sub_box_num + if( in_block_bd(r, sub_box_bd(:,i))) then + which_sub_box = i + exit + end if + end do + return + end subroutine in_sub_box end module box \ No newline at end of file diff --git a/src/call_mode.f90 b/src/call_mode.f90 index f571520..fb187c1 100644 --- a/src/call_mode.f90 +++ b/src/call_mode.f90 @@ -1,4 +1,4 @@ -subroutine call_mode(arg_num,mode) +subroutine call_mode(arg_pos,mode) !This code is used to parse the command line argument for the mode information and calls the required !mode module. @@ -9,16 +9,16 @@ subroutine call_mode(arg_num,mode) implicit none - integer, intent(in) :: arg_num + integer, intent(out) :: arg_pos character(len=100), intent(in) :: mode select case(mode) case('--create') - call create + call create(arg_pos) case('--convert') - call convert + call convert(arg_pos) case('--merge') - call merge + call merge(arg_pos) case default print *, "Mode ", trim(adjustl(mode)), " currently not accepted. Please check documentation for ", & "accepted modes and rerun." diff --git a/src/elements.f90 b/src/elements.f90 index 28e0e5e..b4e59be 100644 --- a/src/elements.f90 +++ b/src/elements.f90 @@ -3,16 +3,17 @@ module elements !This module contains the elements data structures, structures needed for building regions !and operations that are done on elements use parameters + use functions use subroutines implicit none !Data structures used to represent the CAC elements. Each index represents an element character(len=100), allocatable :: type_ele(:) !Element type - integer, allocatable :: size_ele(:), lat_ele(:) !Element siz + integer, allocatable :: size_ele(:), lat_ele(:), sbox_ele(:) !Element size real(kind=dp), allocatable :: r_node(:,:,:,:) !Nodal position array - integer :: ele_num=0 !Number of elements - integer :: node_num=0 !Total number of nodes + integer, save :: ele_num !Number of elements + integer, save :: node_num !Total number of nodes !Data structure used to represent atoms integer, allocatable :: type_atom(:)!atom type @@ -38,6 +39,7 @@ module elements !This can be easily increased with no change to efficiency integer :: max_basisnum, basisnum(10) !Max basis atom number, number of basis atoms in each lattice type integer :: basis_type(10,10) + real(kind=dp) :: lapa(10) public contains @@ -85,6 +87,9 @@ module elements max_basisnum = 0 basisnum(:) = 0 ng_node(:) = 0 + node_num = 0 + ele_num = 0 + atom_num = 0 end subroutine lattice_init subroutine cell_init(lapa,esize,ele_type, orient_mat, cell_mat) @@ -98,10 +103,28 @@ module elements real(kind=dp), dimension(3,max_ng_node), intent(out) :: cell_mat + integer :: inod, i + real(kind=dp), dimension(3,max_ng_node) :: adjustVar + + adjustVar(:,:) = 0.0_dp + select case(trim(ele_type)) case('fcc') - cell_mat(:,1:8) = lapa * ((esize-1)*matmul(orient_mat, fcc_cell)) + if(lmpcac) then + do inod = 1, 8 + do i = 1,3 + if(is_equal(cubic_cell(i, inod),0.0_dp)) then + adjustVar(i,inod) = -0.5_dp + else + adjustVar(i, inod) = 0.5_dp + end if + end do + end do + adjustVar(:,1:8) = matmul(fcc_mat, adjustVar(:,1:8)) + end if + cell_mat(:, 1:8) = fcc_cell + adjustVar(:,1:8) + cell_mat(:,1:8) = lapa * ((esize-1)*matmul(orient_mat, cell_mat(:,1:8))) case default print *, "Element type ", trim(ele_type), " currently not accepted" stop @@ -118,7 +141,7 @@ module elements !Allocate element arrays if(n > 0) then - allocate(type_ele(n), size_ele(n), lat_ele(n), r_node(3,max_basisnum, max_ng_node,n), & + allocate(type_ele(n), size_ele(n), lat_ele(n), sbox_ele(n), r_node(3,max_basisnum, max_ng_node,n), & stat=allostat) if(allostat > 0) then print *, "Error allocating element arrays in elements.f90 because of: ", allostat @@ -157,12 +180,17 @@ module elements allocate(temp_int(n+ele_num+buffer_size)) temp_int(1:ele_size) = lat_ele temp_int(ele_size+1:) = 0 - call move_alloc(temp_int(1:ele_size), lat_ele) + call move_alloc(temp_int, lat_ele) allocate(temp_int(n+ele_num+buffer_size)) temp_int(1:ele_size) = size_ele temp_int(ele_size+1:) = 0 - call move_alloc(temp_int(1:ele_size), size_ele) + call move_alloc(temp_int, size_ele) + + allocate(temp_int(n+ele_num+buffer_size)) + temp_int(1:ele_size) = lat_ele + temp_int(ele_size+1:) = 0 + call move_alloc(temp_int, sbox_ele) allocate(char_temp(n+ele_num+buffer_size)) char_temp(1:ele_size) = type_ele @@ -188,9 +216,9 @@ module elements end if end subroutine - subroutine add_element(type, size, lat, r) + subroutine add_element(type, size, lat, sbox, r) !Subroutine which adds an element to the element arrays - integer, intent(in) :: size, lat + integer, intent(in) :: size, lat, sbox character(len=100), intent(in) :: type real(kind=dp), intent(in) :: r(3, max_basisnum, max_ng_node) @@ -198,6 +226,7 @@ module elements type_ele(ele_num) = type size_ele(ele_num) = size lat_ele(ele_num) = lat + sbox_ele(ele_num) = sbox r_node(:,:,:,ele_num) = r(:,:,:) node_num = node_num + ng_node(lat) @@ -225,8 +254,11 @@ module elements exists = .false. do i=1, 10 - if(type == type_to_name(i)) exists = .true. - inttype = i + if(type == type_to_name(i)) then + exists = .true. + inttype = i + exit + end if end do if (exists.eqv..false.) then @@ -349,4 +381,26 @@ module elements return end subroutine rhombshape + subroutine delete_atoms(num, index) + !This subroutine deletes atoms from the atom arrays + integer, intent(in) :: num + integer, intent(inout), dimension(num) :: index + + integer :: i, j + + call heapsort(index) + + !We go from largest index to smallest index just to make sure that we don't miss + !accidentally overwrite values which need to be deleted + do i = num, 1, -1 + if(index(i) == atom_num) then + r_atom(:,index(i)) = 0.0_dp + type_atom(index(i)) = 0 + else + r_atom(:,index(i)) = r_atom(:, atom_num) + type_atom(index(i)) = type_atom(atom_num) + end if + atom_num = atom_num - 1 + end do + end subroutine end module elements \ No newline at end of file diff --git a/src/functions.f90 b/src/functions.f90 index eb8e813..82bcbcd 100644 --- a/src/functions.f90 +++ b/src/functions.f90 @@ -232,4 +232,22 @@ END FUNCTION StrDnCase end if return end function is_equal + + pure function unitvec(n,vec) + integer, intent(in) :: n + real(kind=dp), intent(in) :: vec(n) + real(kind=dp) :: unitvec(n) + + unitvec = vec/norm2(vec) + return + end function unitvec + + pure function norm_dis(rl,rk) + !This just returns the magnitude of the vector between two points + real(kind=dp), dimension(3), intent(in) :: rl, rk + real(kind=dp) :: norm_dis(4) + + norm_dis(1:3) = (rk - rl) + norm_dis(4) = norm2(rk-rl) + end function end module functions diff --git a/src/io.f90 b/src/io.f90 index 20fac52..e5b098d 100644 --- a/src/io.f90 +++ b/src/io.f90 @@ -9,6 +9,7 @@ module io integer :: outfilenum = 0, infilenum = 0 character(len=100) :: outfiles(10), infiles(10) + public contains @@ -58,13 +59,18 @@ module io cycle end if select case(temp_outfile(scan(temp_outfile,'.',.true.)+1:)) - case('xyz', 'lmp', 'vtk', 'mb') + 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." + 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 @@ -72,7 +78,6 @@ module io end subroutine get_out_file - subroutine write_out !This subroutine loops over alll of the outfile types defined and calls the correct writing subroutine @@ -92,6 +97,10 @@ module io 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" @@ -107,16 +116,10 @@ module io !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 :: node_num, i, inod, ibasis + integer :: i, inod, ibasis open(unit=11, file=trim(adjustl(file)), action='write', status='replace',position='rewind') - !Calculate total node number - node_num=0 - do i = 1, ele_num - node_num = node_num + basisnum(lat_ele(i))*ng_node(lat_ele(i)) - end do - !Write total number of atoms + elements write(11, '(i16)') node_num+atom_num @@ -197,6 +200,87 @@ module io 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 @@ -253,7 +337,7 @@ module io do i = 1, ele_num do inod=1, ng_node(lat_ele(i)) do ibasis = 1, basisnum(lat_ele(i)) - write(11, '(3f23.1)') sum(r_node(:,:,inod,i),2)/basisnum(lat_ele(i)) + write(11, '(3f23.15)') sum(r_node(:,:,inod,i),2)/basisnum(lat_ele(i)) end do end do end do @@ -273,6 +357,123 @@ module io 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, lat_size, inod, ibasis, ip + 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 + 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) + 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 @@ -296,11 +497,13 @@ module io 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(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 @@ -313,7 +516,7 @@ module io !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) + 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) @@ -321,8 +524,10 @@ module io end do end do + close(11) end subroutine write_mb + !!!!!!!!!!!!! Below are subroutines for reading files !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! subroutine get_in_file(filename) @@ -394,10 +599,12 @@ module io 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 + integer :: i, j, k, n, inod, ibasis, type, size, in_atoms, in_eles, new_atom_types, & + new_type_to_type(10), new_lattice_types, sbox 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') @@ -427,21 +634,36 @@ module io 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) - + read(11,*) ((sub_box_array_bd(j, k, sub_box_num+i), j = 1, 2), k = 1, 2) end do - sub_box_num = sub_box_num + n + + !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, *) atom_types, (type_to_name(i), i = 1, atom_types) + 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,*) lattice_types, (basisnum(i), i = 1, lattice_types), (ng_node(i), i = 1, lattice_types) + 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 = 1, lattice_types) - + 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) !Read number of elements and atoms and allocate arrays read(11, *) in_atoms, in_eles call grow_ele_arrays(in_eles, in_atoms) @@ -450,23 +672,31 @@ module io !Read the atoms do i = 1, in_atoms read(11,*) j, type, r(:) - call add_atom(type, r+newdisplace) + 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 + read(11, *) n, 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, type, r_innode) + type = type + lattice_types + call add_element(etype, size, type, sbox+n, 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 + + + sub_box_num = sub_box_num + n + end subroutine read_mb -end module io \ No newline at end of file +end module io diff --git a/src/main.f90 b/src/main.f90 index c7ac008..ed34c53 100644 --- a/src/main.f90 +++ b/src/main.f90 @@ -17,25 +17,59 @@ program main use io - integer :: arg_num - character(len=100) :: mode + integer :: i, end_mode_arg, arg_num, arg_pos + character(len=100) :: argument !Call initialization functions call lattice_init call box_init + end_mode_arg = 0 ! Command line parsing arg_num = command_argument_count() !Determine if a mode is being used and what it is. The first argument has to be the mode !if a mode is being used - call get_command_argument(1, mode) + call get_command_argument(1, argument) - mode = trim(adjustl(mode)) - if (mode(1:2) == '--') then - call call_mode(arg_num, mode) + argument = trim(adjustl(argument)) + if (argument(1:2) == '--') then + call call_mode(end_mode_arg, argument) end if - !Finish by writing the files + !Check to make sure a mode was called + if (end_mode_arg==0) then + stop "Nothing to do, please run cacmb using an available mode" + end if + !Now we loop through all of the arguments and check for passed options or for a filename to be written out + arg_pos = end_mode_arg + do while(.true.) + !Exit the loop if we are done reading + if(arg_pos > arg_num) exit + + call get_command_argument(arg_pos, argument) + + !Check to see if a filename was passed + if(scan(argument,'.',.true.) > 0) then + call get_out_file(argument) + arg_pos = arg_pos + 1 + + !Check to see if an option has been passed + else if(argument(1:1) == '-') then + call call_option(argument, arg_pos) + !Otherwise print that the argument is not accepted and move on + else + print *, trim(adjustl(argument)), " is not accepted. Skipping to next argument" + arg_pos = arg_pos + 1 + end if + end do + + !Check to make sure a file was passed to be written out and then write out + ! Before building do a check on the file + if (outfilenum == 0) then + argument = 'none' + call get_out_file(argument) + end if call write_out + end program main \ No newline at end of file diff --git a/src/mode_convert.f90 b/src/mode_convert.f90 index d6e1d9b..1f8a6bd 100644 --- a/src/mode_convert.f90 +++ b/src/mode_convert.f90 @@ -8,8 +8,9 @@ module mode_convert public contains - subroutine convert + subroutine convert(arg_pos) !This subroutine converts a single input file from one format to another + integer, intent(out) :: arg_pos character(len=100) :: infile, outfile real(kind = dp) :: temp_box_bd(6) !We have to allocate the element and atom arrays with a size of 1 for the read in code to work @@ -19,10 +20,7 @@ module mode_convert call get_in_file(infile) call read_in(1, (/0.0_dp,0.0_dp,0.0_dp/), temp_box_bd) call grow_box(temp_box_bd) - - !Now get the outfile, writing is done after all the codes complete - call get_command_argument(3, outfile) - call get_out_file(outfile) + arg_pos = 3 end subroutine convert end module mode_convert \ No newline at end of file diff --git a/src/mode_create.f90 b/src/mode_create.f90 index b82cc82..9463e92 100644 --- a/src/mode_create.f90 +++ b/src/mode_create.f90 @@ -12,8 +12,8 @@ module mode_create character(len=100) :: name, element_type real(kind = dp) :: lattice_parameter, orient(3,3), cell_mat(3,8), box_len(3), basis(3,3), origin(3), maxlen(3), & - orient_inv(3,3), box_vert(3,8), maxbd(3), lattice_space(3) - integer :: esize, duplicate(3), ix, iy, iz, box_lat_vert(3,8), lat_ele_num, lat_atom_num, bd_in_lat(6), & + orient_inv(3,3), box_vert(3,8), maxbd(3), lattice_space(3), duplicate(3) + integer :: esize, ix, iy, iz, box_lat_vert(3,8), lat_ele_num, lat_atom_num, bd_in_lat(6), & basis_pos(3,10) logical :: dup_flag, dim_flag @@ -21,11 +21,12 @@ module mode_create public contains - subroutine create() + subroutine create(arg_pos) ! Main subroutine which controls execution character(len=100) :: textholder - + integer, intent(out) :: arg_pos + integer :: i, ibasis, inod real(kind=dp), allocatable :: r_node_temp(:,:,:) @@ -45,29 +46,22 @@ module mode_create lat_atom_num = 0 !First we parse the command - call parse_command() + call parse_command(arg_pos) - ! Before building do a check on the file - if (outfilenum == 0) then - textholder = 'none' - call get_out_file(textholder) - end if - !Now we setup the unit element and call other init subroutines call def_ng_node(1, element_type) allocate(r_node_temp(3,max_basisnum,max_ng_node)) - if(dup_flag) then + !Get the inverse orientation matrix we will need later + call matrix_inverse(orient,3,orient_inv) - !We initialize the cell with a lattice_parameter of 1 because we will add the lattice parameter later - call cell_init(1.0_dp, esize, element_type, orient, cell_mat) + if(dup_flag) then - + !Define box vertices do i = 1, 8 - box_vert(:,i) = duplicate(:)*esize*lattice_space(:)*cubic_cell(:,i) + origin(:) + box_vert(:,i) = duplicate(:)*esize*lattice_space(:)*cubic_cell(:,i) + (origin(:)/lattice_parameter) end do - call matrix_inverse(orient,3,orient_inv) !Now get the rotated box vertex positions in lattice space. Should be integer units box_lat_vert = int(matmul(fcc_inv, matmul(orient_inv, box_vert)))+1 !Find the new maxlen @@ -76,21 +70,25 @@ module mode_create box_bd(2*i) = maxval(box_vert(i,:)) - 0.25_dp*lattice_space(i) box_bd(2*i-1) = origin(i)-0.25_dp*lattice_space(i) end do - !and then call the build function with the correct transformation matrix - select case(trim(adjustl(element_type))) - case('fcc') - call build_with_rhomb(box_lat_vert, fcc_mat) - case default - print *, "Element type ", trim(adjustl(element_type)), " not accepted in mode create, please specify a supported ", & - "element type" - stop 3 - end select - !Now that it is multiply by the lattice parameter - box_bd = box_bd*lattice_parameter + else if(dim_flag) then - continue + !As a note everything is defined so that the lattice parameter is multiplied in at the end + !so we have to divide all the real Angstroms units by the lattice parameter + + !Define box_vertices + do i = 1, 8 + box_vert(:,i) = (cubic_cell(:,i)*box_len(:) + origin(:))/lattice_parameter + end do + !Now get the rotated box vertex positions in lattice space. Should be integer units + box_lat_vert = int(matmul(fcc_inv, matmul(orient_inv, box_vert)))+1 + + !Now get the box_bd in lattice units + do i = 1, 3 + box_bd(2*i) = (box_len(i)+origin(i))/lattice_parameter + box_bd(2*i-1) = origin(i)/lattice_parameter + end do else call cell_init(lattice_parameter, esize, element_type, orient, cell_mat) @@ -107,11 +105,24 @@ module mode_create box_bd(2*i) = maxval(r_node_temp(i,:,:)) box_bd(2*i-1) = origin(i) end do - call add_element(element_type, esize, 1, r_node_temp) + call add_element(element_type, esize, 1, 1, r_node_temp) end if !If we passed the dup_flag or dim_flag then we have to convert the lattice points and add them to the atom/element arrays if(dup_flag.or.dim_flag) then + !Call the build function with the correct transformation matrix + select case(trim(adjustl(element_type))) + case('fcc') + + call build_with_rhomb(box_lat_vert, fcc_mat) + case default + print *, "Element type ", trim(adjustl(element_type)), " not accepted in mode create, please specify a supported ", & + "element type" + stop 3 + end select + !Now that it is built multiply by the lattice parameter + box_bd = box_bd*lattice_parameter + !Allocate variables call alloc_ele_arrays(lat_ele_num, lat_atom_num*basisnum(1)) if(lat_atom_num > 0) then @@ -130,7 +141,7 @@ module mode_create r_node_temp(:,ibasis,inod) = (r_lat(:,inod,i)*lattice_parameter)+basis_pos(:,ibasis) end do end do - call add_element(element_type, esize, 1, r_node_temp) + call add_element(element_type, esize, 1, 1, r_node_temp) end do end if end if @@ -145,10 +156,10 @@ module mode_create sub_box_array_bd(2,2,1) = ele_num end subroutine create !This subroutine parses the command and pulls out information needed for mode_create - subroutine parse_command() + subroutine parse_command(arg_pos) - - integer :: arg_pos, ori_pos, i, j, arglen, stat + integer, intent(out) :: arg_pos + integer :: ori_pos, i, j, arglen, stat character(len=100) :: textholder character(len=8) :: orient_string @@ -208,33 +219,32 @@ module mode_create !If the duplicate command is passed then we extract the information on the new bounds. case('duplicate') + if(dim_flag) STOP "Both duplicate and dim options cannot be used in mode_create" dup_flag = .true. do i = 1, 3 call get_command_argument(arg_pos, textholder) read(textholder, *) duplicate(i) arg_pos = arg_pos + 1 end do - + case('dim') + if(dup_flag) STOP "Both duplicate and dim options cannot be used in mode_create" + dim_flag = .true. + do i = 1, 3 + call get_command_argument(arg_pos, textholder) + read(textholder, *) box_len(i) + arg_pos = arg_pos + 1 + end do case('origin') do i = 1, 3 call get_command_argument(arg_pos, textholder) read(textholder, *) origin(i) arg_pos = arg_pos + 1 end do - !If a filetype is passed then we add name.ext to the outfiles list - case('xyz') - textholder = trim(adjustl(name)) //'.xyz' - call get_out_file(textholder) case default - !Check to see if it is an option command, if so then mode_create must be finished - if(textholder(1:1) == '-') then - exit - - !Check to see if a filename was passed - elseif(scan(textholder,'.',.true.) > 0) then - call get_out_file(textholder) - end if + !If it isn't an option then you have to exit + arg_pos = arg_pos -1 + exit end select end do @@ -268,8 +278,9 @@ module mode_create !Now normalize the orientation matrix orient = matrix_normal(orient,3) - !Set lattice_num to 1 + !Set lattice_num to 1 and add the lattice_parameter to the elements module lattice paramter variable lattice_types = 1 + lapa(1) = lattice_parameter !If we haven't defined a basis then define the basis and add the default basis atom type and position if (basisnum(1) == 0) then diff --git a/src/mode_merge.f90 b/src/mode_merge.f90 index 0919b70..cfb4273 100644 --- a/src/mode_merge.f90 +++ b/src/mode_merge.f90 @@ -12,13 +12,14 @@ module mode_merge public contains - subroutine merge + subroutine merge(arg_pos) + integer, intent(out) :: arg_pos integer :: i real(kind=dp) :: displace(3), temp_box_bd(6) !First we parse the merge command - call parse_command + call parse_command(arg_pos) !Now loop over all files and stack them do i = 1, in_num @@ -44,10 +45,12 @@ module mode_merge return end subroutine merge - subroutine parse_command + subroutine parse_command(arg_pos) + + integer, intent(out) :: arg_pos character(len=100) :: textholder - integer :: i, stat, arglen, arg_pos + integer :: i, stat, arglen !Get dimension to concatenate along call get_command_argument(2, dim, arglen) @@ -74,27 +77,22 @@ module mode_merge end do !Set argpos accordingly - arg_pos = 3+in_num+1 + arg_pos = 3+in_num !Now options loop !Check for optional keywords do while(.true.) if(arg_pos > command_argument_count()) exit !Pull out the next argument which should either be a keyword or an option + arg_pos=arg_pos+1 call get_command_argument(arg_pos, textholder) textholder=adjustl(textholder) - arg_pos=arg_pos+1 !Choose what to based on what the option string is select case(trim(textholder)) case default - !Check to see if it is an option command, if so then mode_create must be finished - if(textholder(1:1) == '-') then - exit - !Check to see if a filename was passed - elseif(scan(textholder,'.',.true.) > 0) then - call get_out_file(textholder) - end if + !If it isn't an available option to mode merge then we just exit + exit end select end do diff --git a/src/opt_disl.f90 b/src/opt_disl.f90 new file mode 100644 index 0000000..4510ede --- /dev/null +++ b/src/opt_disl.f90 @@ -0,0 +1,520 @@ +module opt_disl + + !This module contains all code associated with dislocations + + use parameters + use elements + use subroutines + use box + implicit none + + + real(kind=dp), dimension(3) :: line, slip_plane, centroid!dislocation line, slip plane vectors, centroid, + real(kind=dp) :: burgers(3) !burgers vector of loop + real(kind=dp) :: poisson, char_angle, lattice_parameter!Poisson ratio and character angle, lattice_parameter for burgers vector + character(len=10) :: lattice + character(len=1) :: loop_normal + real(kind=dp) :: loop_radius !Dislocation loop radius + + real(kind=dp) :: b !burgers vector + + + public + contains + + subroutine dislocation(option, arg_pos) + + !Main calling function for all codes related to dislocations + + character(len=100), intent(in) :: option + integer, intent(inout) :: arg_pos + + + select case(trim(adjustl(option))) + case('-dislgen') + call parse_dislgen(arg_pos) + call dislgen + case('-disloop') + call parse_disloop(arg_pos) + call disloop + end select + end subroutine dislocation + + subroutine parse_dislgen(arg_pos) + + !Parse dislgen command + + integer, intent(inout) :: arg_pos + + integer :: i,arglen + character(len=8) :: ori_string + character(len=100) :: textholder + + !Parse all of the commands + arg_pos = arg_pos + 1 + line(:) = 0.0_dp + call get_command_argument(arg_pos, ori_string, arglen) + if (arglen==0) STOP "Missing line vector in dislgen command" + call parse_ori_vec(ori_string, line) + + arg_pos=arg_pos + 1 + slip_plane(:) = 0.0_dp + call get_command_argument(arg_pos, ori_string, arglen) + if (arglen==0) STOP "Missing plane vector in dislgen command" + call parse_ori_vec(ori_string, slip_plane) + + do i = 1, 3 + arg_pos = arg_pos + 1 + call get_command_argument(arg_pos, textholder, arglen) + if (arglen==0) STOP "Missing centroid in dislgen command" + call parse_pos(i, textholder, centroid(i)) + end do + + print *, centroid + + arg_pos = arg_pos + 1 + call get_command_argument(arg_pos, textholder, arglen) + if (arglen==0) STOP "Missing character angle in dislgen command" + read(textholder, *) char_angle + + + arg_pos = arg_pos + 1 + call get_command_argument(arg_pos, textholder, arglen) + if (arglen==0) STOP "Missing poisson in dislgen command" + read(textholder, *) poisson + + arg_pos = arg_pos + 1 + call get_command_argument(arg_pos, lattice, arglen) + if (arglen==0) STOP "Missing lattice in dislgen command" + + arg_pos = arg_pos + 1 + call get_command_argument(arg_pos, textholder, arglen) + if (arglen==0) STOP "Missing lattice parameter in dislgen command" + read(textholder, *) lattice_parameter + + arg_pos = arg_pos + 1 + !Now set the vurgers vector based on the lattice paarameter and lattice type + select case(lattice) + case('fcc') + b = lattice_parameter / sqrt(2.0_dp) + ! case('bcc') + ! b = lattice_parameter * sqrt(3.0_dp) / 2.0_dp + case default + print *, 'Error: Lattice structure', lattice, ' is not accepted for dislgen option' + STOP + end select + + end subroutine parse_dislgen + + subroutine dislgen + !This subroutine creates the actual dislocation + + integer :: i, sub_box, inod, ibasis + real(kind=dp) :: ss_ori(3,3), ss_inv(3,3), be, bs, slipx(3), disp_transform(3,3), inv_transform(3,3), & + actan, r(3), disp(3) + + !Calculate screw and edge burgers vectors + be = sin(char_angle*pi/180.0_dp)*b + bs = cos(char_angle*pi/180.0_dp)*b + + !Figure out which sub box you are in so you can access it's orientation, this code will not work + !with overlapping sub_boxes + do i = 1, sub_box_num + if(in_block_bd(centroid, sub_box_bd(:,i))) then + sub_box = i + exit + end if + end do + + !Construct the slip system orientation matrix in an unrotated system + slipx = cross_product(slip_plane, line) + ss_ori(1,:) = unitvec(3,slipx) + ss_ori(2,:) = unitvec(3,slip_plane) + ss_ori(3,:) = unitvec(3,line) + call matrix_inverse(ss_ori, 3, ss_inv) + + !Apply the rotation + disp_transform = matmul(sub_box_ori(:,:,i), ss_inv) + call matrix_inverse(disp_transform,3,inv_transform) + + if(atom_num > 0) then + do i = 1, atom_num + r=r_atom(:,i) - centroid + r=matmul(inv_transform, r) + if (r(1) == 0) then + actan=pi/2 + else + actan = datan2(r(2),r(1)) + end if + + if ((r(1)**2 + r(2)**2) == 0) cycle + + !This is the elastic displacement field for dislocation according to Hirth and Lowe + disp(1) = be/(2.0_dp*pi) * (actan + (r(1)*r(2))/(2.0_dp*(1.0_dp-poisson)*(r(1)**2.0_dp + r(2)**2.0_dp))) + disp(2) = -be/(2.0_dp*pi)*((1.0_dp-2.0_dp*poisson)/(4.0_dp-4.0_dp*poisson) * & + log(r(1)**2.0_dp + r(2)**2.0_dp) & + + (r(1)**2.0_dp - r(2)**2.0_dp)/(4.0_dp*(1.0_dp-poisson)& + *(r(1)**2.0_dp+r(2)**2.0_dp))) + disp(3) = bs/(2.0_dp*pi) * actan + + !This transforms the displacement to the correct orientation + disp = matmul(disp_transform, disp) + + r_atom(:,i) = r_atom(:,i) + disp + end do + end if + + if(ele_num > 0) then + do i = 1, ele_num + do inod=1, ng_node(lat_ele(i)) + do ibasis = 1, basisnum(lat_ele(i)) + r = r_node(:,ibasis,inod,i) + r = matmul(inv_transform, r) + if (r(1) == 0) then + actan = pi/2 + else + actan = datan2(r(2),r(1)) + end if + + if ((r(1)**2 + r(2)**2) == 0) cycle + + !This is the elastic displacement field for dislocation according to Hirth and Lowe + disp(1) = be/(2.0_dp*pi) * (actan + (r(1)*r(2))/(2.0_dp*(1.0_dp-poisson)*(r(1)**2.0_dp + r(2)**2.0_dp))) + disp(2) = -be/(2.0_dp*pi)*((1.0_dp-2.0_dp*poisson)/(4.0_dp-4.0_dp*poisson) * & + log(r(1)**2.0_dp + r(2)**2.0_dp) & + + (r(1)**2.0_dp - r(2)**2.0_dp)/(4.0_dp*(1.0_dp-poisson)& + *(r(1)**2.0_dp+r(2)**2.0_dp))) + disp(3) = bs/(2.0_dp*pi) * actan + + + disp = matmul(disp_transform, disp) + r_node(:,ibasis,inod,i) = r_node(:,ibasis,inod,i) + disp + end do + end do + end do + end if + + end subroutine dislgen + + subroutine parse_disloop(arg_pos) + !This subroutine parses the disloop command + + integer, intent(inout) :: arg_pos + + integer :: i,arglen, sbox + character(len=8) :: ori_string + character(len=100) :: textholder + + !Parse all of the commands + arg_pos = arg_pos + 1 + loop_normal = ' ' + call get_command_argument(arg_pos, loop_normal, arglen) + if (arglen==0) STOP "Missing loop_normal in disloop command" + !Convert the loop_normal to the dimension + select case(loop_normal) + case('x','X', 'y', 'Y', 'z', 'Z') + continue + case default + print *, "Dimension argument must either be x, y, or z not", loop_normal + stop 3 + end select + + arg_pos = arg_pos + 1 + loop_radius = 0 + call get_command_argument(arg_pos, textholder, arglen) + if (arglen==0) STOP "Missing loop_size in disloop command" + read(textholder, *) loop_radius + + do i = 1, 3 + arg_pos = arg_pos + 1 + call get_command_argument(arg_pos, textholder, arglen) + if (arglen==0) STOP "Missing centroid in disloop command" + call parse_pos(i, textholder, centroid(i)) + end do + + burgers(:) = 0.0_dp + do i = 1, 3 + arg_pos = arg_pos + 1 + call get_command_argument(arg_pos, textholder, arglen) + if (arglen==0) STOP "Missing burgers vector in disloop command" + read(textholder, *) burgers(i) + end do + + arg_pos = arg_pos + 1 + call get_command_argument(arg_pos, textholder, arglen) + if (arglen==0) STOP "Missing poisson ratio in disloop command" + read(textholder, *) poisson + + arg_pos = arg_pos + 1 + + !Now check to make sure that the dimension selected is actually a 1 1 1 direction. + ! call in_sub_box(centroid, sbox) + ! if(.not.((abs(sub_box_ori(loop_normal,1,sbox)) == abs(sub_box_ori(loop_normal,2,sbox))).and. & + ! (abs(sub_box_ori(loop_normal,2,sbox)) == abs(sub_box_ori(loop_normal,3,sbox))).and. & + ! (abs(sub_box_ori(loop_normal,3,sbox)) == abs(sub_box_ori(loop_normal,1,sbox))))) then + + ! print *, "The selected dimension ", loop_normal, " for sub_box ", sbox, " is ", & + ! sub_box_ori(loop_normal,:,sbox), " which is not in the (111) family of planes" + ! STOP 3 + ! end if + + + end subroutine + + !Code for the creation of dislocation loops is based on functions from atomsk + !which is available from https://atomsk.univ-lille.fr/. They have been adapted to fit cacmb. + subroutine disloop + !This subroutine applies the displacement field for a dislocation loop to all atoms and elements. + integer :: a1, a2, a3 !New directions + integer :: i, j, inod, ibasis, Npoints + real(kind = dp) :: perimeter, angle, theta, omega, xA(3), xB(3), xC(3), u(3) + real(kind=dp), dimension(:,:), allocatable :: xloop !coordinate of points forming loop + + if(allocated(xLoop)) deallocate(xLoop) + + !Define new directions + select case(loop_normal) + case('x','X') + !Loop in (y,z) plane + a1 = 2 + a2 = 3 + a3 = 1 + case('y','Y') + !Loop in (x,z) plane + a1 = 3 + a2 = 1 + a3 = 2 + case default + !Loop in (x,y) plane + a1 = 1 + a2 = 2 + a3 = 3 + end select + + !Calculate loop perimeter + perimeter = 2.0_dp*pi*loop_radius + + !Define the number of points forming the loop + ! The following criteria are used as a trade-off between + ! good accuracy and computational efficiency: + ! - each dislocation segment should have a length of 5 angströms; + ! - the loop should contain at least 3 points + ! (for very small loops, this will result in segments shorter than 5 A); + ! - there should not be more than 100 points + ! (for very large loops, this will result in segments longer than 5 A). + Npoints = MAX( 3 , MIN( NINT(perimeter/5.d0) , 100 ) ) + + !angle between two consecutive points + theta = 2.0_dp*pi / dble(Npoints) + + !allocate xLoop + allocate(xLoop(Npoints,3)) + xLoop(:,:) = 0.0_dp + + !Calculate the position of each point in the loop + angle = 0.0_dp + do i = 1, size(xLoop,1) + xLoop(i,a1) = centroid(a1) + loop_radius*dcos(angle) + xLoop(i,a2) = centroid(a2) + loop_radius*dsin(angle) + xLoop(i,a3) = centroid(a3) + ! Increment angle for next point + angle = angle + theta + end do + + !Now actually calculate the displacement created by a loop for every atom + do i = 1, atom_num + u = 0.0_dp + omega = 0.0_dp + xC(:) = centroid - r_atom(:,i) + + !Loop over all dislocation segments + do j = 1, size(xLoop,1) + !Coordinates of point A + if (j ==1) then + xA(:) = xLoop(size(xLoop,1),:) - r_atom(:,i) + else + xA(:) = xLoop(j-1, :) - r_atom(:,i) + end if + + !Coordinates of point B + xB(:) = xLoop(j,:) - r_atom(:,i) + + !Displacement due to solid angle + omega = omega + SolidAngle(xA, xB, xC) + !Displacement due to elasticity + u(:) = u(:) + DisloSeg_displacement_iso(xA, xB, burgers(:), poisson) + end do + + !Total displacement + u=u(:) + burgers(:) * omega + + !Apply displacement to atom + r_atom(:,i) = r_atom(:,i) + u(:) + end do + + !Repeat for element nodes + do i = 1, ele_num + do inod =1, ng_node(lat_ele(i)) + do ibasis = 1, basisnum(lat_ele(i)) + u = 0.0_dp + omega = 0.0_dp + xC(:) = centroid - r_node(:,ibasis,inod,i) + + !Loop over all dislocation segments + do j = 1, size(xLoop,1) + !Coordinates of point A + if (j ==1) then + xA(:) = xLoop(size(xLoop,1),:) - r_node(:,ibasis,inod,i) + else + xA(:) = xLoop(j-1, :) - r_node(:,ibasis,inod,i) + end if + + !Coordinates of point B + xB(:) = xLoop(j,:) - r_node(:,ibasis,inod,i) + + !Displacement due to solid angle + omega = omega + SolidAngle(xA, xB, xC) + !Displacement due to elasticity + u(:) = u(:) + DisloSeg_displacement_iso(xA, xB, burgers(:), poisson) + end do + + !Total displacement + u=u(:) + burgers(:) * omega + + !Apply displacement to atom + r_node(:,ibasis,inod,i) = r_node(:,ibasis,inod,i) + u(:) + end do + end do + end do + return + end subroutine + + !******************************************************** + ! SOLIDANGLE + ! Calculate solid angle (normalized by 4*pi) used to obtain the + ! displacement created by a dislocation triangle loop ABC at the origin + ! (field point = origin) + ! Ref.: Van Oosterom, A. and Strackee, J., + ! The Solid Angle of a Plane Triangle, + ! IEEE Transactions on Biomedical Engineering BME-30, 125 (1983). + !******************************************************** + FUNCTION SolidAngle(xA, xB, xC) RESULT(Omega) + ! + IMPLICIT NONE + ! + ! Extremities of the triangle loop + REAL(dp),DIMENSION(3),INTENT(IN) :: xA, xB, xC + ! + ! Solid angle (normalized by 4*pi) + REAL(dp):: omega + REAL(dp),PARAMETER:: factor=1.d0/(2.d0*pi) + ! + REAL(dp) :: rA, rB, rC, numerator, denominator + ! + rA = norm2(xA) + rB = norm2(xB) + rC = norm2(xC) + ! + numerator = TRIPLE_PRODUCT( xA, xB, xC ) + denominator = rA*rB*rC + DOT_PRODUCT( xA, xB )*rC & + & + DOT_PRODUCT( xB, xC )*rA + DOT_PRODUCT( xC, xA )*rB + ! + omega = factor*ATAN2( numerator, denominator ) + ! + END FUNCTION SolidAngle + + !******************************************************** + ! DISLOSEG_DISPLACEMENT_ISO + ! Calculate displacement created by dislocation segment AB + ! once the solid angle part has been removed + ! Isotropic elastic calculation with nu Poisson coef. + ! Ref.: Eq. (1) in Barnett, D. M. + ! The Displacement Field of a Triangular Dislocation Loop + ! Philos. Mag. A, 1985, 51, 383-387 + !******************************************************** + FUNCTION DisloSeg_displacement_iso(xA, xB, b, nu) RESULT(u) + ! + IMPLICIT NONE + REAL(dp),DIMENSION(3),INTENT(IN):: xA, xB ! Extremities of the segment + REAL(dp),DIMENSION(3),INTENT(IN):: b ! Burgers vector + REAL(dp),INTENT(IN):: nu ! Poisson coefficient + REAL(dp),DIMENSION(3):: u ! Displacement + REAL(dp):: rA, rB + REAL(dp),DIMENSION(1:3):: tAB, nAB + ! + rA = norm2(xA) + rB = norm2(xB) + ! + ! Tangent vector + tAB(:) = xB(:) - xA(:) + tAB(:) = tAB(:)/norm2(tAB) + ! + ! Normal vector + nAB(:) = CROSS_PRODUCT(xA,xB) + nAB(:) = nAB(:)/norm2(nAB) + ! + u(:) = ( -(1.d0-2.d0*nu)*CROSS_PRODUCT(b, tAB)* & + & LOG( (rB + DOT_PRODUCT(xB,tAB))/(rA + DOT_PRODUCT(xA,tAB)) ) & + & + DOT_PRODUCT(b,nAB)*CROSS_PRODUCT(xB/rB-xA/rA,nAB) ) & + & /(8.d0*pi*(1.d0-nu)) + ! + END FUNCTION DisloSeg_displacement_iso +! + !This code simply creates a planar vacancy cluster and does not apply the dislocation loop displacement field. + ! subroutine disloop + ! !This subroutine actually creates the dislocation loop. + + ! real(kind=dp) :: neighbor_dis(loop_size), temp_box(6), dis + ! integer :: i, j, index(loop_size) + + ! neighbor_dis(:) = HUGE(1.0_dp) + ! index(:) = 0 + + ! !First find the nearest atom to the centroid + ! do i = 1, atom_num + ! if(norm2(r_atom(:,i) - centroid) < neighbor_dis(1)) then + ! neighbor_dis(1) = norm2(r_atom(:,i) - centroid) + ! index(1) = i + ! end if + ! end do + + ! !Define a new box, this box tries to isolate all atoms on the plane of the atom + ! !closest to the user defined centroid. + ! temp_box(:) = box_bd(:) + ! temp_box(2*loop_normal) = r_atom(loop_normal,index(1)) + 10.0_dp**(-2.0_dp) + ! temp_box(2*loop_normal-1) = r_atom(loop_normal,index(1)) - 10.0_dp**(-2.0_dp) + + ! !Now reset the list for the scanning algorithm + ! index(1) = 0 + ! neighbor_dis(1) = HUGE(1.0_dp) + + ! !Now scan over all atoms again and find the closest loop_size number of atoms to the initial atom + ! !that reside on the same plane. + + ! do i = 1, atom_num + ! !Check to see if it is on the same plane + ! if (in_block_bd(r_atom(:,i), temp_box)) then + ! dis = norm2(r_atom(:,i) - centroid) + ! do j = 1, loop_size + ! !Check to see if it is closer than other atoms + ! if (dis < neighbor_dis(j)) then + ! !Move values in the neighbor array and add the new neighbor + ! if(j < loop_size) then + ! neighbor_dis(j+1:loop_size) = neighbor_dis(j:loop_size-1) + ! index(j+1:loop_size) = index(j:loop_size-1) + ! end if + ! neighbor_dis(j) = dis + ! index(j) = i + ! exit + ! end if + ! end do + ! end if + ! end do + + ! !Now delete the atoms + ! call delete_atoms(loop_size, index) + + ! return + ! end subroutine disloop + +end module opt_disl \ No newline at end of file diff --git a/src/parameters.f90 b/src/parameters.f90 index 0443622..6054140 100644 --- a/src/parameters.f90 +++ b/src/parameters.f90 @@ -2,7 +2,14 @@ module parameters implicit none + !Default precision integer, parameter :: dp= selected_real_kind(15,307) + !Parameters for floating point tolerance real(kind=dp), parameter :: lim_zero = epsilon(1.0_dp), & lim_large = huge(1.0_dp) -end module parameters \ No newline at end of file + logical, save :: lmpcac + + !Numeric constants + real(kind=dp), parameter :: pi = 3.14159265358979323846_dp + +end module parameters diff --git a/src/subroutines.f90 b/src/subroutines.f90 index 0682037..330fbca 100644 --- a/src/subroutines.f90 +++ b/src/subroutines.f90 @@ -1,6 +1,7 @@ module subroutines use parameters use functions + use box implicit none integer :: allostat, deallostat @@ -145,4 +146,107 @@ module subroutines return end subroutine matrix_inverse + subroutine parse_ori_vec(ori_string, ori_vec) + !This subroutine parses a string to vector in the format [ijk] + character(len=8), intent(in) :: ori_string + real(kind=dp), dimension(3), intent(out) :: ori_vec + + integer :: i, ori_pos, stat + + ori_pos=2 + do i = 1,3 + if (ori_string(ori_pos:ori_pos) == '-') then + ori_pos = ori_pos + 1 + read(ori_string(ori_pos:ori_pos), *, iostat=stat) ori_vec(i) + if (stat>0) STOP "Error reading orientation value" + ori_vec(i) = -ori_vec(i) + ori_pos = ori_pos + 1 + else + read(ori_string(ori_pos:ori_pos), *, iostat=stat) ori_vec(i) + if(stat>0) STOP "Error reading orientation value" + ori_pos=ori_pos + 1 + end if + end do + + return + end subroutine parse_ori_vec + + subroutine parse_pos(i, pos_string, pos) + !This subroutine parses the pos command allowing for command which include inf + integer, intent(in) :: i !The dimension of the position + character(len=100), intent(in) :: pos_string !The position string + real(kind=dp), intent(out) :: pos !The output parsed position value + + integer :: iospara + if(trim(adjustl(pos_string)) == 'inf') then + pos=box_bd(2*i) + else if(trim(adjustl(pos_string)) == '-inf') then + pos=box_bd(2*i-1) + else if ((index(pos_string,'-') > 0).and.(index(pos_string,'inf')>0)) then + !Now extract the number we are reducing from infinity + read(pos_string(index(pos_string,'-')+1:), *, iostat=iospara) pos + pos = box_bd(2*i) - pos + else if ((index(pos_string,'+') > 0).and.(index(pos_string,'inf')>0)) then + !Now extract the number we are reducing from infinity + read(pos_string(index(pos_string,'+')+1:), *, iostat=iospara) pos + pos = box_bd(2*i-1) + pos + else if ((index(pos_string,'*') > 0).and.(index(pos_string,'inf')>0)) then + !Now extract the number we are reducing from infinity + read(pos_string(index(pos_string,'*')+1:), *, iostat=iospara) pos + pos = (box_bd(2*i)-box_bd(2*i-1))*pos + else + read(pos_string, *, iostat=iospara) pos + end if + + if (iospara > 0) then + print *, "Error reading position argument ", trim(adjustl(pos_string)), ". Please reformat and try again." + end if + end subroutine parse_pos + + subroutine heapsort(a) + + integer, intent(in out) :: a(0:) + integer :: start, n, bottom + real :: temp + + n = size(a) + do start = (n - 2) / 2, 0, -1 + call siftdown(a, start, n); + end do + + do bottom = n - 1, 1, -1 + temp = a(0) + a(0) = a(bottom) + a(bottom) = temp; + call siftdown(a, 0, bottom) + end do + + end subroutine heapsort + + subroutine siftdown(a, start, bottom) + + integer, intent(in out) :: a(0:) + integer, intent(in) :: start, bottom + integer :: child, root + real :: temp + + root = start + do while(root*2 + 1 < bottom) + child = root * 2 + 1 + + if (child + 1 < bottom) then + if (a(child) < a(child+1)) child = child + 1 + end if + + if (a(root) < a(child)) then + temp = a(child) + a(child) = a (root) + a(root) = temp + root = child + else + return + end if + end do + + end subroutine siftdown end module subroutines \ No newline at end of file