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https://github.com/QuantumPackage/qp2.git
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521 lines
16 KiB
Fortran
521 lines
16 KiB
Fortran
program localization
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implicit none
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call set_classes_loc
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call run_localization
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call unset_classes_loc
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end
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! Variables:
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! | pre_rot(mo_num, mo_num) | double precision | Matrix for the pre rotation |
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! | R(mo_num,mo_num) | double precision | Rotation matrix |
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! | tmp_R(:,:) | double precision | Rottation matrix in a subsapce |
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! | prev_mos(ao_num, mo_num) | double precision | Previous mo_coef |
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! | spatial_extent(mo_num) | double precision | Spatial extent of the orbitals |
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! | criterion | double precision | Localization criterion |
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! | prev_criterion | double precision | Previous criterion |
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! | criterion_model | double precision | Estimated next criterion |
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! | rho | double precision | Ratio to measure the agreement between the model |
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! | | | and the reality |
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! | delta | double precision | Radisu of the trust region |
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! | norm_grad | double precision | Norm of the gradient |
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! | info | integer | for dsyev from Lapack |
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! | max_elem | double precision | maximal element in the gradient |
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! | v_grad(:) | double precision | Gradient |
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! | H(:,:) | double precision | Hessian (diagonal) |
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! | e_val(:) | double precision | Eigenvalues of the hessian |
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! | W(:,:) | double precision | Eigenvectors of the hessian |
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! | tmp_x(:) | double precision | Step in 1D (in a subaspace) |
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! | tmp_m_x(:,:) | double precision | Step in 2D (in a subaspace) |
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! | tmp_list(:) | double precision | List of MOs in a mo_class |
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! | i,j,k | integer | Indexes in the full MO space |
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! | tmp_i, tmp_j, tmp_k | integer | Indexes in a subspace |
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! | l | integer | Index for the mo_class |
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! | key(:) | integer | Key to sort the eigenvalues of the hessian |
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! | nb_iter | integer | Number of iterations |
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! | must_exit | logical | To exit the trust region loop |
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! | cancel_step | logical | To cancel a step |
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! | not_*converged | logical | To localize the different mo classes |
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! | t* | double precision | To measure the time |
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! | n | integer | mo_num*(mo_num-1)/2, number of orbital parameters |
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! | tmp_n | integer | dim_subspace*(dim_subspace-1)/2 |
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! | | | Number of dimension in the subspace |
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! Variables in qp_edit for the localization:
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! | localization_method |
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! | localization_max_nb_iter |
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! | default_mo_class |
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! | thresh_loc_max_elem_grad |
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! | kick_in_mos |
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! | angle_pre_rot |
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! + all the variables for the trust region
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! Cf. qp_edit orbital optimization
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subroutine run_localization
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include 'pi.h'
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BEGIN_DOC
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! Orbital localization
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END_DOC
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implicit none
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! Variables
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double precision, allocatable :: pre_rot(:,:), R(:,:)
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double precision, allocatable :: prev_mos(:,:), spatial_extent(:), tmp_R(:,:)
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double precision :: criterion, norm_grad
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integer :: i,j,k,l,p, tmp_i, tmp_j, tmp_k
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integer :: info
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integer :: n, tmp_n, tmp_list_size
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double precision, allocatable :: v_grad(:), H(:), tmp_m_x(:,:), tmp_x(:),W(:),e_val(:)
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double precision :: max_elem, t1, t2, t3, t4, t5, t6
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integer, allocatable :: tmp_list(:), key(:)
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double precision :: prev_criterion, rho, delta, criterion_model
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integer :: nb_iter, nb_sub_iter
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logical :: not_converged, not_core_converged
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logical :: not_act_converged, not_inact_converged, not_virt_converged
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logical :: use_trust_region, must_exit, cancel_step,enforce_step_cancellation
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n = mo_num*(mo_num-1)/2
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! Allocation
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allocate(spatial_extent(mo_num))
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allocate(pre_rot(mo_num, mo_num), R(mo_num, mo_num))
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allocate(prev_mos(ao_num, mo_num))
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! Locality before the localization
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call compute_spatial_extent(spatial_extent)
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! Choice of the method
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print*,''
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print*,'Localization method:',localization_method
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if (localization_method == 'boys') then
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print*,'Foster-Boys localization'
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elseif (localization_method == 'pipek') then
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print*,'Pipek-Mezey localization'
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else
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print*,'Unknown localization_method, please select boys or pipek'
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call abort
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endif
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print*,''
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! Localization criterion (FB, PM, ...) for each mo_class
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print*,'### Before the pre rotation'
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! Debug
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if (debug_hf) then
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print*,'HF energy:', HF_energy
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endif
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do l = 1, 4
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if (l==1) then ! core
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tmp_list_size = dim_list_core_orb
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elseif (l==2) then ! act
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tmp_list_size = dim_list_act_orb
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elseif (l==3) then ! inact
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tmp_list_size = dim_list_inact_orb
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else ! virt
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tmp_list_size = dim_list_virt_orb
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endif
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! Allocation tmp array
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allocate(tmp_list(tmp_list_size))
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! To give the list of MOs in a mo_class
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if (l==1) then ! core
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tmp_list = list_core
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elseif (l==2) then
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tmp_list = list_act
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elseif (l==3) then
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tmp_list = list_inact
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else
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tmp_list = list_virt
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endif
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if (tmp_list_size >= 2) then
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call criterion_localization(tmp_list_size, tmp_list,criterion)
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print*,'Criterion:', criterion, mo_class(tmp_list(1))
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endif
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deallocate(tmp_list)
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enddo
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! Debug
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!print*,'HF', HF_energy
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! Loc
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! Pre rotation, to give a little kick in the MOs
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call apply_pre_rotation()
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! Criterion after the pre rotation
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! Localization criterion (FB, PM, ...) for each mo_class
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print*,'### After the pre rotation'
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! Debug
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if (debug_hf) then
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touch mo_coef
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print*,'HF energy:', HF_energy
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endif
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do l = 1, 4
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if (l==1) then ! core
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tmp_list_size = dim_list_core_orb
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elseif (l==2) then ! act
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tmp_list_size = dim_list_act_orb
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elseif (l==3) then ! inact
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tmp_list_size = dim_list_inact_orb
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else ! virt
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tmp_list_size = dim_list_virt_orb
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endif
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if (tmp_list_size >= 2) then
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! Allocation tmp array
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allocate(tmp_list(tmp_list_size))
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! To give the list of MOs in a mo_class
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if (l==1) then ! core
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tmp_list = list_core
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elseif (l==2) then
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tmp_list = list_act
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elseif (l==3) then
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tmp_list = list_inact
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else
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tmp_list = list_virt
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endif
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call criterion_localization(tmp_list_size, tmp_list,criterion)
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print*,'Criterion:', criterion, trim(mo_class(tmp_list(1)))
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deallocate(tmp_list)
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endif
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enddo
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! Debug
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!print*,'HF', HF_energy
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print*,''
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print*,'========================'
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print*,' Orbital localization'
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print*,'========================'
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print*,''
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!Initialization
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not_converged = .TRUE.
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! To do the localization only if there is at least 2 MOs
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if (dim_list_core_orb >= 2) then
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not_core_converged = .TRUE.
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else
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not_core_converged = .FALSE.
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endif
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if (dim_list_act_orb >= 2) then
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not_act_converged = .TRUE.
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else
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not_act_converged = .FALSE.
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endif
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if (dim_list_inact_orb >= 2) then
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not_inact_converged = .TRUE.
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else
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not_inact_converged = .FALSE.
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endif
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if (dim_list_virt_orb >= 2) then
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not_virt_converged = .TRUE.
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else
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not_virt_converged = .FALSE.
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endif
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! Loop over the mo_classes
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do l = 1, 4
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if (l==1) then ! core
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not_converged = not_core_converged
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tmp_list_size = dim_list_core_orb
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elseif (l==2) then ! act
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not_converged = not_act_converged
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tmp_list_size = dim_list_act_orb
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elseif (l==3) then ! inact
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not_converged = not_inact_converged
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tmp_list_size = dim_list_inact_orb
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else ! virt
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not_converged = not_virt_converged
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tmp_list_size = dim_list_virt_orb
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endif
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! Next iteration if converged = true
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if (.not. not_converged) then
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cycle
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endif
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! Allocation tmp array
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allocate(tmp_list(tmp_list_size))
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! To give the list of MOs in a mo_class
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if (l==1) then ! core
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tmp_list = list_core
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elseif (l==2) then
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tmp_list = list_act
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elseif (l==3) then
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tmp_list = list_inact
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else
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tmp_list = list_virt
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endif
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! Display
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if (not_converged) then
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print*,''
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print*,'###', trim(mo_class(tmp_list(1))), 'MOs ###'
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print*,''
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endif
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! Size for the 2D -> 1D transformation
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tmp_n = tmp_list_size * (tmp_list_size - 1)/2
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! Without hessian + trust region
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if (.not. localization_use_hessian) then
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! Allocation of temporary arrays
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allocate(v_grad(tmp_n), tmp_m_x(tmp_list_size, tmp_list_size))
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allocate(tmp_R(tmp_list_size, tmp_list_size), tmp_x(tmp_n))
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! Criterion
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call criterion_localization(tmp_list_size, tmp_list, prev_criterion)
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! Init
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nb_iter = 0
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delta = 1d0
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!Loop
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do while (not_converged)
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print*,''
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print*,'***********************'
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print*,'Iteration', nb_iter
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print*,'***********************'
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print*,''
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! Angles of rotation
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call theta_localization(tmp_list, tmp_list_size, tmp_m_x, max_elem)
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tmp_m_x = - tmp_m_x * delta
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! Rotation submatrix
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call rotation_matrix(tmp_m_x, tmp_list_size, tmp_R, tmp_list_size, tmp_list_size, &
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info, enforce_step_cancellation)
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! To ensure that the rotation matrix is unitary
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if (enforce_step_cancellation) then
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print*, 'Step cancellation, too large error in the rotation matrix'
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delta = delta * 0.5d0
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cycle
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else
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delta = min(delta * 2d0, 1d0)
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endif
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! Full rotation matrix and application of the rotation
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call sub_to_full_rotation_matrix(tmp_list_size, tmp_list, tmp_R, R)
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call apply_mo_rotation(R, prev_mos)
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! Update the needed data
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call update_data_localization()
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! New criterion
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call criterion_localization(tmp_list_size, tmp_list, criterion)
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print*,'Criterion:', trim(mo_class(tmp_list(1))), nb_iter, criterion
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print*,'Max elem :', max_elem
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print*,'Delta :', delta
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nb_iter = nb_iter + 1
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! Exit
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if (nb_iter >= localization_max_nb_iter .or. dabs(max_elem) < thresh_loc_max_elem_grad) then
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not_converged = .False.
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endif
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enddo
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! Save the changes
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call update_data_localization()
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call save_mos()
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TOUCH mo_coef
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! Deallocate
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deallocate(v_grad, tmp_m_x, tmp_list)
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deallocate(tmp_R, tmp_x)
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! Trust region
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else
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! Allocation of temporary arrays
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allocate(v_grad(tmp_n), H(tmp_n), tmp_m_x(tmp_list_size, tmp_list_size))
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allocate(tmp_R(tmp_list_size, tmp_list_size))
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allocate(tmp_x(tmp_n), W(tmp_n), e_val(tmp_n), key(tmp_n))
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! ### Initialization ###
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delta = 0d0 ! can be deleted (normally)
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nb_iter = 0 ! Must start at 0 !!!
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rho = 0.5d0 ! Must be 0.5
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! Compute the criterion before the loop
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call criterion_localization(tmp_list_size, tmp_list, prev_criterion)
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! Loop until the convergence
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do while (not_converged)
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print*,''
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print*,'***********************'
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print*,'Iteration', nb_iter
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print*,'***********************'
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print*,''
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! Gradient
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call gradient_localization(tmp_n, tmp_list_size, tmp_list, v_grad, max_elem, norm_grad)
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! Diagonal hessian
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call hessian_localization(tmp_n, tmp_list_size, tmp_list, H)
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! Diagonalization of the diagonal hessian by hands
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!call diagonalization_hessian(tmp_n,H,e_val,w)
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do i = 1, tmp_n
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e_val(i) = H(i)
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enddo
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! Key list for dsort
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do i = 1, tmp_n
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key(i) = i
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enddo
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! Sort of the eigenvalues
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call dsort(e_val, key, tmp_n)
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! Eigenvectors
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W = 0d0
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do i = 1, tmp_n
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W(i) = dble(key(i))
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enddo
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! To enter in the loop just after
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cancel_step = .True.
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nb_sub_iter = 0
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! Loop to reduce the trust radius until the criterion decreases and rho >= thresh_rho
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do while (cancel_step)
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print*,'-----------------------------'
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print*, mo_class(tmp_list(1))
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print*,'Iteration:', nb_iter
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print*,'Sub iteration:', nb_sub_iter
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print*,'Max elem grad:', max_elem
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print*,'-----------------------------'
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! Hessian,gradient,Criterion -> x
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call trust_region_step_w_expected_e(tmp_n,1, H, W, e_val, v_grad, prev_criterion, &
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rho, nb_iter, delta, criterion_model, tmp_x, must_exit)
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! Internal loop exit condition
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if (must_exit) then
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print*,'trust_region_step_w_expected_e sent: Exit'
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exit
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endif
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! 1D tmp -> 2D tmp
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call vec_to_mat_v2(tmp_n, tmp_list_size, tmp_x, tmp_m_x)
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! Rotation submatrix (square matrix tmp_list_size by tmp_list_size)
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call rotation_matrix(tmp_m_x, tmp_list_size, tmp_R, tmp_list_size, tmp_list_size, &
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info, enforce_step_cancellation)
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if (enforce_step_cancellation) then
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print*, 'Step cancellation, too large error in the rotation matrix'
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rho = 0d0
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cycle
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endif
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! tmp_R to R, subspace to full space
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call sub_to_full_rotation_matrix(tmp_list_size, tmp_list, tmp_R, R)
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! Rotation of the MOs
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call apply_mo_rotation(R, prev_mos)
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! Update the things related to mo_coef
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call update_data_localization()
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! Update the criterion
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call criterion_localization(tmp_list_size, tmp_list, criterion)
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print*,'Criterion:', trim(mo_class(tmp_list(1))), nb_iter, criterion
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! Criterion -> step accepted or rejected
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call trust_region_is_step_cancelled(nb_iter, prev_criterion, criterion, &
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criterion_model, rho, cancel_step)
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! Cancellation of the step, previous MOs
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if (cancel_step) then
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mo_coef = prev_mos
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endif
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nb_sub_iter = nb_sub_iter + 1
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enddo
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!call save_mos() !### depend of the time for 1 iteration
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! To exit the external loop if must_exti = .True.
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if (must_exit) then
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exit
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endif
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! Step accepted, nb iteration + 1
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nb_iter = nb_iter + 1
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! External loop exit conditions
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if (DABS(max_elem) < thresh_loc_max_elem_grad) then
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not_converged = .False.
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endif
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if (nb_iter > localization_max_nb_iter) then
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not_converged = .False.
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endif
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enddo
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! Deallocation of temporary arrays
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deallocate(v_grad, H, tmp_m_x, tmp_R, tmp_list, tmp_x, W, e_val, key)
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! Save the MOs
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call save_mos()
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TOUCH mo_coef
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! Debug
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if (debug_hf) then
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touch mo_coef
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print*,'HF energy:', HF_energy
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endif
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endif
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enddo
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! Seems unecessary
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TOUCH mo_coef
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! To sort the MOs using the diagonal elements of the Fock matrix
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if (sort_mos_by_e) then
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call run_sort_by_fock_energies()
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endif
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! Debug
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if (debug_hf) then
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touch mo_coef
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print*,'HF energy:', HF_energy
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endif
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! Locality after the localization
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call compute_spatial_extent(spatial_extent)
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end
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