add mo localization

2024-11-18 11:23:38 +01:00 · 2023-04-18 13:22:46 +02:00 · 2023-04-18 13:22:46 +02:00 · d6f7ec60f8
commit d6f7ec60f8
parent c687569bf4
16 changed files with 6054 additions and 0 deletions
--- a/src/mo_localization/84.mo_localization.bats
+++ b/src/mo_localization/84.mo_localization.bats
@ -0,0 +1,97 @@
 #!/usr/bin/env bats
 source $QP_ROOT/tests/bats/common.bats.sh
 source $QP_ROOT/quantum_package.rc
 zero () {
    if [ -z "$1" ]; then echo 0.0; else echo $1; fi
 }
 function run() {
  thresh1=1e-10
  thresh2=1e-12
  thresh3=1e-4
  test_exe scf || skip
  qp set_file $1
  qp edit --check
  qp reset -d
  qp set_frozen_core
  qp set localization localization_method boys
  file="$(echo $1 | sed 's/.ezfio//g')"
  energy="$(cat $1/hartree_fock/energy)"
  fb_err1="$(qp run debug_gradient_loc | grep 'Max error' | tail -n 1 | awk '{print $3}')"
  fb_err2="$(qp run debug_hessian_loc | grep 'Max error' | tail -n 1 | awk '{print $3}')"
  qp run localization > $file.loc.out
  fb_energy="$(qp run print_energy | grep -A 1 'Nuclear repulsion energy' | tail -n 1 )"
  fb_c="$(cat $file.loc.out | grep 'Criterion:Core' | tail -n 1 | awk '{print $3}')i"
  fb_i="$(cat $file.loc.out | grep 'Criterion:Inactive' | tail -n 1 | awk '{print $3}')"
  fb_a="$(cat $file.loc.out | grep 'Criterion:Active' | tail -n 1 | awk '{print $3}')"
  fb_v="$(cat $file.loc.out | grep 'Criterion:Virtual' | tail -n 1 | awk '{print $3}')"
  qp reset -a
  qp run scf
  qp set_frozen_core
  qp set localization localization_method pipek 
  pm_err1="$(qp run debug_gradient_loc | grep 'Max error' | tail -n 1 | awk '{print $3}')"
  pm_err2="$(qp run debug_hessian_loc | grep 'Max error' | tail -n 1 | awk '{print $3}')"
  qp run localization > $file.loc.out
  pm_c="$(cat $file.loc.out | grep 'Criterion:Core' | tail -n 1 | awk '{print $3}')i"
  pm_i="$(cat $file.loc.out | grep 'Criterion:Inactive' | tail -n 1 | awk '{print $3}')"
  pm_a="$(cat $file.loc.out | grep 'Criterion:Active' | tail -n 1 | awk '{print $3}')"
  pm_v="$(cat $file.loc.out | grep 'Criterion:Virtual' | tail -n 1 | awk '{print $3}')"
  pm_energy="$(qp run print_energy | grep -A 1 'Nuclear repulsion energy' | tail -n 1 )"
  qp set localization localization_method boys
  qp reset -a
  qp run scf
  qp set_frozen_core
  eq $energy $fb_energy $thresh1 
  eq $fb_err1 0.0 $thresh2
  eq $fb_err2 0.0 $thresh2
  eq $energy $pm_energy $thresh1
  eq $pm_err1 0.0 $thresh2
  eq $pm_err2 0.0 $thresh2
  fb_c=$(zero $fb_c)
  fb_i=$(zero $fb_i)
  fb_a=$(zero $fb_a)
  fb_v=$(zero $fb_v)
  pm_c=$(zero $pm_c)
  pm_i=$(zero $pm_i)
  pm_a=$(zero $pm_a)
  pm_v=$(zero $pm_v)
  eq $fb_c $2 $thresh3
  eq $fb_i $3 $thresh3
  eq $fb_a $4 $thresh3
  eq $fb_v $5 $thresh3
  eq $pm_c $6 $thresh3
  eq $pm_i $7 $thresh3
  eq $pm_a $8 $thresh3
  eq $pm_v $9 $thresh3
 }
@test "b2_stretched" {
 run  b2_stretched.ezfio -32.1357551678876 -47.0041982094667 0.0 -223.470015856259 -1.99990778964451 -2.51376723927071 0.0 -12.8490602539275
 }
@test "clo" {
 run  clo.ezfio -44.1624001765291 -32.4386660941387 0.0 -103.666309287187 -5.99985418946811 -5.46871580225222 0.0 -20.2480064922275
 }
@test "clf" {
 run  clf.ezfio -47.5143398826967 -35.7206886315104 0.0 -107.043029033468 -5.99994222062230 -6.63916513458470 0.0 -19.7035159913484
 }
@test "h2o2" {
 run  h2o2.ezfio -7.76848143170524 -30.9694344369829 0.0 -175.898343829453 -1.99990497554575 -5.62980322957485 0.0 -33.5699813186666
 }
@test "h2o" {
 run  h2o.ezfio 0.0 -2.52317434969591 0.0 -45.3136377925359 0.0 -3.01248365356981 0.0 -22.4470831240924
 }
@test "h3coh" {
 run  h3coh.ezfio -3.66763692804590 -24.0463089480870 0.0 -111.485948435075 -1.99714061342078 -4.89242181322988 0.0 -23.6405412057679
 }
@test "n2h4" {
 run  n2h4.ezfio -7.46608163002070 -35.7632174051822 0.0 -305.913449004632 -1.99989326143356 -4.62496615892268 0.0 -51.5171904685553
 }
--- a/src/mo_localization/EZFIO.cfg
+++ b/src/mo_localization/EZFIO.cfg
@ -0,0 +1,54 @@
 [localization_method]
 type: character*(32)
 doc: Method for the orbital localization. boys: Foster-Boys, pipek: Pipek-Mezey.
 interface: ezfio,provider,ocaml
 default: boys
 [localization_max_nb_iter]
 type: integer
 doc: Maximal number of iterations for the orbital localization.
 interface: ezfio,provider,ocaml
 default: 1000
 [localization_use_hessian]
 type: logical
 doc: If true, it uses the trust region algorithm with the gradient and the diagonal of the hessian. Else it computes the rotation between each pair of MOs that should be applied to maximize/minimize the localization criterion. The last option is not easy to converge. 
 interface: ezfio,provider,ocaml
 default: true
 [auto_mo_class]
 type: logical
 doc: If true, set automatically the classes.
 interface: ezfio,provider,ocaml
 default: true
 [thresh_loc_max_elem_grad]
 type: double precision
 doc: Threshold for the convergence, the localization exits when the largest element in the gradient is smaller than thresh_localization_max_elem_grad.
 interface: ezfio,provider,ocaml
 default: 1.e-6
 [kick_in_mos]
 type: logical
 doc: If True, it applies a rotation of an angle angle_pre_rot between the MOs of a same mo_class before the localization.
 interface: ezfio,provider,ocaml
 default: true
 [angle_pre_rot]
 type: double precision
 doc: To define the angle for the rotation of the MOs before the localization (in rad).
 interface: ezfio,provider,ocaml
 default: 0.1
 [sort_mos_by_e]
 type: logical
 doc: If True, the MOs are sorted using the diagonal elements of the Fock matrix.
 interface: ezfio,provider,ocaml
 default: false
 [debug_hf]
 type: logical
 doc: If True, prints the HF energy before/after the different steps of the localization. Only for debugging.
 interface: ezfio,provider,ocaml
 default: false
--- a/src/mo_localization/NEED
+++ b/src/mo_localization/NEED
@ -0,0 +1,3 @@
 hartree_fock
 utils_trust_region
 determinants
--- a/src/mo_localization/README.md
+++ b/src/mo_localization/README.md
@ -0,0 +1,113 @@
 # Orbital localisation
 To localize the MOs:  
 ```
 qp run localization  
 ```
 By default, the different otbital classes are automatically set by splitting  
 the orbitales in the following classes:  
 - Core -> Core  
 - Active, doubly occupied -> Inactive  
 - Active, singly occupied -> Active  
 - Active, empty -> Virtual  
 - Deleted -> Deleted  
 The orbitals will be localized among each class, excpect the deleted ones.
 If you want to choose another splitting, you can set
 ```
 qp set mo_localization auto_mo_class false
 ```
 and define the classes with
 ```
 qp set_mo_class -c [] -a [] -v [] -i [] -d [] 
 ```
 for more information
 ```
 qp set_mo_class -q
 ```
 We don't care about the name of the   
 mo classes. The algorithm just localizes all the MOs of  
 a given class between them, for all the classes, except the deleted MOs.  
 If you are using the last option don't forget to reset the initial mo classes  
 after the localization.
 Before the localization, a kick is done for each mo class  
 (except the deleted ones) to break the MOs. This is done by   
 doing a given rotation between the MOs.
 This feature can be removed by setting:
 ```
 qp set localization kick_in_mos false
 ```
 and the default angle for the rotation can be changed with:
 ```
 qp set localization angle_pre_rot 1e-3 # or something else
 ```
 After the localization, the MOs of each class (except the deleted ones)  
 can be sorted between them using the diagonal elements of  
 the fock matrix with:
 ```
 qp set localization sort_mos_by_e true
 ```
 You can check the Hartree-Fock energy before/during/after the localization  
 by putting (only for debugging):
 ```
 qp set localization debug_hf true 
 ```
 ## Foster-Boys & Pipek-Mezey
 Foster-Boys:  
 ``` 
 qp set localization localization_method boys 
 ``` 
 Pipek-Mezey:  
 ``` 
 qp set localization localization_method pipek 
 ``` 
 # Break the spatial symmetry of the MOs
 This program work exactly as the localization.  
 To break the spatial symmetry of the MOs:   
 ```
 qp run break_spatial_sym
 ```
 The default angle for the rotations is too big for this kind of
 application, a value between 1e-3 and 1e-6 should break the spatial
 symmetry with just a small change in the energy:
 ```
 qp set localization angle_pre_rot 1e-3
 ``` 
 # With or without hessian + trust region
 With hessian +  trust region
 ```
 qp set localization localisation_use_hessian true
 ```
 It uses the trust region algorithm with the diagonal of the hessian of the 
 localization criterion with respect to the MO rotations.   
 Without the hessian and the trust region
 ```
 qp set localization localisation_use_hessian false
 ```
 By doing so it does not require to store the hessian but the
 convergence is not easy, in particular for virtual MOs.
 It seems that it not possible to converge with Pipek-Mezey
 localization with this approach.
 # Parameters
 Some other parameters are available for the localization (qp edit for more details).
 # Tests
 ```
 qp test
 ```
 # Org files
 The org files are stored in the directory org in order to avoid overwriting on user changes.
 The org files can be modified, to export the change to the source code, run
 ```
 ./TANGLE_org_mode.sh
 mv *.irp.f ../.
 ```
--- a/src/mo_localization/break_spatial_sym.irp.f
+++ b/src/mo_localization/break_spatial_sym.irp.f
@ -0,0 +1,27 @@
 ! ! A small program to break the spatial symmetry of the MOs.
 ! ! You have to defined your MO classes or set security_mo_class to false
 ! ! with:
 ! ! qp set orbital_optimization security_mo_class false
 ! ! The default angle for the rotations is too big for this kind of
 ! ! application, a value between 1e-3 and 1e-6 should break the spatial
 ! ! symmetry with just a small change in the energy. 
 program break_spatial_sym
  !BEGIN_DOC
  ! Break the symmetry of the MOs with a rotation
  !END_DOC
  implicit none
  kick_in_mos = .True.
  TOUCH kick_in_mos
  call set_classes_loc 
  call apply_pre_rotation
  call unset_classes_loc 
 end
--- a/src/mo_localization/debug_gradient_loc.irp.f
+++ b/src/mo_localization/debug_gradient_loc.irp.f
@ -0,0 +1,65 @@
 program debug_gradient_loc
  !BEGIN_DOC
  ! Check if the gradient is correct
  !END_DOC
  implicit none
  integer :: list_size, n
  integer, allocatable :: list(:)
  double precision, allocatable :: v_grad(:), v_grad2(:)
  double precision :: norm, max_elem, threshold, max_error
  integer :: i, nb_error
  threshold = 1d-12
  list_size = dim_list_act_orb
  allocate(list(list_size))
  list = list_act
  n = list_size*(list_size-1)/2
  allocate(v_grad(n),v_grad2(n))
  if (localization_method == 'boys') then
    print*,'Foster-Boys'
    call gradient_FB(n,list_size,list,v_grad,max_elem,norm)
    call gradient_FB_omp(n,list_size,list,v_grad2,max_elem,norm)
  elseif (localization_method == 'pipek') then
    print*,'Pipek-Mezey'
    call gradient_PM(n,list_size,list,v_grad,max_elem,norm)
    call gradient_PM(n,list_size,list,v_grad2,max_elem,norm) 
  else
    print*,'Unknown localization_method, please select boys or pipek'
    call abort
  endif
  do i = 1, n
    print*,i,v_grad(i)
  enddo
  v_grad = v_grad - v_grad2
  nb_error = 0
  max_elem = 0d0
  do i = 1, n
    if (dabs(v_grad(i)) > threshold) then
      print*,v_grad(i)
      nb_error = nb_error + 1
      if (dabs(v_grad(i)) > max_elem) then
        max_elem = v_grad(i)
      endif
    endif
  enddo
  print*,'Threshold error', threshold
  print*, 'Nb error', nb_error
  print*,'Max error', max_elem
  deallocate(v_grad,v_grad2)
 end
--- a/src/mo_localization/debug_hessian_loc.irp.f
+++ b/src/mo_localization/debug_hessian_loc.irp.f
@ -0,0 +1,65 @@
 program debug_hessian_loc
  !BEGIN_DOC
  ! Check if the hessian is correct
  !END_DOC
  implicit none
  integer :: list_size, n
  integer, allocatable :: list(:)
  double precision, allocatable :: H(:), H2(:)
  double precision :: threshold, max_error, max_elem
  integer :: i, nb_error
  threshold = 1d-12
  list_size = dim_list_act_orb
  allocate(list(list_size))
  list = list_act
  n = list_size*(list_size-1)/2
  allocate(H(n),H2(n))
  if (localization_method == 'boys') then
    print*,'Foster-Boys'
    call hessian_FB(n,list_size,list,H)
    call hessian_FB_omp(n,list_size,list,H2)
  elseif(localization_method == 'pipek') then
    print*,'Pipek-Mezey'
    call hessian_PM(n,list_size,list,H)
    call hessian_PM(n,list_size,list,H2)
  else
    print*,'Unknown localization_method, please select boys or pipek'
    call abort
  endif
  do i = 1, n
    print*,i,H(i)
  enddo
  H = H - H2
  nb_error = 0
  max_elem = 0d0
  do i = 1, n
    if (dabs(H(i)) > threshold) then
      print*,H(i)
      nb_error = nb_error + 1
      if (dabs(H(i)) > max_elem) then
        max_elem = H(i)
      endif
    endif
  enddo
  print*,'Threshold error', threshold
  print*, 'Nb error', nb_error
  print*,'Max error', max_elem
  deallocate(H,H2)
 end
--- a/src/mo_localization/kick_the_mos.irp.f
+++ b/src/mo_localization/kick_the_mos.irp.f
@ -0,0 +1,16 @@
 program kick_the_mos
  !BEGIN_DOC
  ! To do a small rotation of the MOs
  !END_DOC
  implicit none
  kick_in_mos = .True.
  TOUCH kick_in_mos
  call set_classes_loc
  call apply_pre_rotation
  call unset_classes_loc
 end
--- a/src/mo_localization/localization.irp.f
+++ b/src/mo_localization/localization.irp.f
@ -0,0 +1,520 @@
 program localization
  implicit none
  call set_classes_loc
  call run_localization
  call unset_classes_loc
 end
 ! Variables:
 ! | pre_rot(mo_num, mo_num)   | double precision | Matrix for the pre rotation                       |
 ! | R(mo_num,mo_num)          | double precision | Rotation matrix                                   |
 ! | tmp_R(:,:)                | double precision | Rottation matrix in a subsapce                    |
 ! | prev_mos(ao_num, mo_num)  | double precision | Previous mo_coef                                  |
 ! | spatial_extent(mo_num)    | double precision | Spatial extent of the orbitals                    |
 ! | criterion                 | double precision | Localization criterion                            |
 ! | prev_criterion            | double precision | Previous criterion                                |
 ! | criterion_model           | double precision | Estimated next criterion                          |
 ! | rho                       | double precision | Ratio to measure the agreement between the model  |
 ! |                           |                  | and the reality                                   |
 ! | delta                     | double precision | Radisu of the trust region                        |
 ! | norm_grad                 | double precision | Norm of the gradient                              |
 ! | info                      | integer          | for dsyev from Lapack                             |
 ! | max_elem                  | double precision | maximal element in the gradient                   |
 ! | v_grad(:)                 | double precision | Gradient                                          |
 ! | H(:,:)                    | double precision | Hessian (diagonal)                                |
 ! | e_val(:)                  | double precision | Eigenvalues of the hessian                        |
 ! | W(:,:)                    | double precision | Eigenvectors of the hessian                       |
 ! | tmp_x(:)                  | double precision | Step in 1D (in a subaspace)                       |
 ! | tmp_m_x(:,:)              | double precision | Step in 2D (in a subaspace)                       |
 ! | tmp_list(:)               | double precision | List of MOs in a mo_class                         |
 ! | i,j,k                     | integer          | Indexes in the full MO space                      |
 ! | tmp_i, tmp_j, tmp_k       | integer          | Indexes in a subspace                             |
 ! | l                         | integer          | Index for the mo_class                            |
 ! | key(:)                    | integer          | Key to sort the eigenvalues of the hessian        |
 ! | nb_iter                   | integer          | Number of iterations                              |
 ! | must_exit                 | logical          | To exit the trust region loop                     |
 ! | cancel_step               | logical          | To cancel a step                                  |
 ! | not_*converged            | logical          | To localize the different mo classes              |
 ! | t*                        | double precision | To measure the time                               |
 ! | n                         | integer          | mo_num*(mo_num-1)/2, number of orbital parameters |
 ! | tmp_n                     | integer          | dim_subspace*(dim_subspace-1)/2                   |
 ! |                           |                  | Number of dimension in the subspace               |
 ! Variables in qp_edit for the localization:
 ! | localization_method      |
 ! | localization_max_nb_iter |
 ! | default_mo_class         |
 ! | thresh_loc_max_elem_grad |
 ! | kick_in_mos              |
 ! | angle_pre_rot            |
 ! + all the variables for the trust region
 ! Cf. qp_edit orbital optimization
 subroutine run_localization
  include 'pi.h'
  BEGIN_DOC
  ! Orbital localization
  END_DOC
  implicit none
  ! Variables
  double precision, allocatable :: pre_rot(:,:), R(:,:)
  double precision, allocatable :: prev_mos(:,:), spatial_extent(:), tmp_R(:,:)
  double precision              :: criterion, norm_grad
  integer                       :: i,j,k,l,p, tmp_i, tmp_j, tmp_k
  integer                       :: info
  integer                       :: n, tmp_n, tmp_list_size
  double precision, allocatable :: v_grad(:), H(:), tmp_m_x(:,:), tmp_x(:),W(:),e_val(:)
  double precision              :: max_elem, t1, t2, t3, t4, t5, t6
  integer, allocatable          :: tmp_list(:), key(:)
  double precision              :: prev_criterion, rho, delta, criterion_model
  integer                       :: nb_iter, nb_sub_iter
  logical                       :: not_converged, not_core_converged
  logical                       :: not_act_converged, not_inact_converged, not_virt_converged
  logical                       :: use_trust_region, must_exit, cancel_step,enforce_step_cancellation
  n = mo_num*(mo_num-1)/2
  ! Allocation
  allocate(spatial_extent(mo_num))
  allocate(pre_rot(mo_num, mo_num), R(mo_num, mo_num))
  allocate(prev_mos(ao_num, mo_num))
  ! Locality before the localization
  call compute_spatial_extent(spatial_extent)
  ! Choice of the method
  print*,''
  print*,'Localization method:',localization_method
  if (localization_method == 'boys') then
    print*,'Foster-Boys localization'
  elseif (localization_method == 'pipek') then
    print*,'Pipek-Mezey localization'
  else
    print*,'Unknown localization_method, please select boys or pipek'
    call abort
  endif
  print*,''
  ! Localization criterion (FB, PM, ...) for each mo_class
  print*,'### Before the pre rotation'
  ! Debug
  if (debug_hf) then
    print*,'HF energy:', HF_energy
  endif
  do l = 1, 4
    if (l==1) then ! core
      tmp_list_size = dim_list_core_orb
    elseif (l==2) then ! act
      tmp_list_size = dim_list_act_orb
    elseif (l==3) then ! inact
      tmp_list_size = dim_list_inact_orb
    else ! virt
      tmp_list_size = dim_list_virt_orb
    endif
     ! Allocation tmp array  
    allocate(tmp_list(tmp_list_size))
    ! To give the list of MOs in a mo_class
    if (l==1) then ! core
      tmp_list = list_core
    elseif (l==2) then
      tmp_list = list_act
    elseif (l==3) then
      tmp_list = list_inact
    else
      tmp_list = list_virt
    endif
    if (tmp_list_size >= 2) then
      call criterion_localization(tmp_list_size, tmp_list,criterion)
      print*,'Criterion:', criterion, mo_class(tmp_list(1))
    endif
    deallocate(tmp_list)    
  enddo
  ! Debug
  !print*,'HF', HF_energy
 ! Loc
 ! Pre rotation, to give a little kick in the MOs
  call apply_pre_rotation()
  ! Criterion after the pre rotation
  ! Localization criterion (FB, PM, ...) for each mo_class
  print*,'### After the pre rotation'
  ! Debug
  if (debug_hf) then
    touch mo_coef
    print*,'HF energy:', HF_energy
  endif
  do l = 1, 4
    if (l==1) then ! core
      tmp_list_size = dim_list_core_orb
    elseif (l==2) then ! act
      tmp_list_size = dim_list_act_orb
    elseif (l==3) then ! inact
      tmp_list_size = dim_list_inact_orb
    else ! virt
      tmp_list_size = dim_list_virt_orb
    endif
    if (tmp_list_size >= 2) then
      ! Allocation tmp array  
      allocate(tmp_list(tmp_list_size))
      ! To give the list of MOs in a mo_class
      if (l==1) then ! core
        tmp_list = list_core
      elseif (l==2) then
        tmp_list = list_act
      elseif (l==3) then
        tmp_list = list_inact
      else
        tmp_list = list_virt
      endif
      call criterion_localization(tmp_list_size, tmp_list,criterion)
      print*,'Criterion:', criterion, trim(mo_class(tmp_list(1)))
      deallocate(tmp_list)    
    endif
  enddo
  ! Debug
  !print*,'HF', HF_energy
  print*,''
  print*,'========================'
  print*,'  Orbital localization'
  print*,'========================'
  print*,'' 
  !Initialization
  not_converged = .TRUE.
  ! To do the localization only if there is at least 2 MOs
  if (dim_list_core_orb >= 2) then
    not_core_converged = .TRUE.
  else
    not_core_converged = .FALSE. 
  endif
  if (dim_list_act_orb >= 2) then
    not_act_converged = .TRUE.
  else
    not_act_converged = .FALSE.
  endif
  if (dim_list_inact_orb >= 2) then
    not_inact_converged = .TRUE.
  else
    not_inact_converged = .FALSE.
  endif
  if (dim_list_virt_orb >= 2) then
    not_virt_converged = .TRUE.
  else
    not_virt_converged = .FALSE.
  endif
  ! Loop over the mo_classes
  do l = 1, 4
    if (l==1) then ! core
      not_converged = not_core_converged
      tmp_list_size = dim_list_core_orb
    elseif (l==2) then ! act
      not_converged = not_act_converged
      tmp_list_size = dim_list_act_orb
    elseif (l==3) then ! inact
      not_converged = not_inact_converged
      tmp_list_size = dim_list_inact_orb
    else ! virt
      not_converged = not_virt_converged
      tmp_list_size = dim_list_virt_orb
    endif
    ! Next iteration if converged = true 
    if (.not. not_converged) then
      cycle
    endif
    ! Allocation tmp array  
    allocate(tmp_list(tmp_list_size))
    ! To give the list of MOs in a mo_class
    if (l==1) then ! core
      tmp_list = list_core
    elseif (l==2) then
      tmp_list = list_act
    elseif (l==3) then
      tmp_list = list_inact
    else
      tmp_list = list_virt
    endif
    ! Display
    if (not_converged) then
      print*,''
      print*,'###', trim(mo_class(tmp_list(1))), 'MOs ###'
      print*,''
    endif
    ! Size for the 2D -> 1D transformation 
    tmp_n = tmp_list_size * (tmp_list_size - 1)/2
    ! Without hessian + trust region 
    if (.not. localization_use_hessian) then
      ! Allocation of temporary arrays
      allocate(v_grad(tmp_n), tmp_m_x(tmp_list_size, tmp_list_size))
      allocate(tmp_R(tmp_list_size, tmp_list_size), tmp_x(tmp_n))
      ! Criterion
      call criterion_localization(tmp_list_size, tmp_list, prev_criterion)
      ! Init
      nb_iter = 0
      delta = 1d0
      !Loop
      do while (not_converged)
        print*,''
        print*,'***********************'
        print*,'Iteration', nb_iter
        print*,'***********************'
        print*,''
        ! Angles of rotation
        call theta_localization(tmp_list, tmp_list_size, tmp_m_x, max_elem)
        tmp_m_x = - tmp_m_x * delta
        ! Rotation submatrix
        call rotation_matrix(tmp_m_x, tmp_list_size, tmp_R, tmp_list_size, tmp_list_size, &
             info, enforce_step_cancellation)
        ! To ensure that the rotation matrix is unitary
        if (enforce_step_cancellation) then
          print*, 'Step cancellation, too large error in the rotation matrix'
          delta = delta * 0.5d0
          cycle
        else
          delta = min(delta * 2d0, 1d0)
        endif
        ! Full rotation matrix and application of the rotation
        call sub_to_full_rotation_matrix(tmp_list_size, tmp_list, tmp_R, R)
        call apply_mo_rotation(R, prev_mos)
        ! Update the needed data
        call update_data_localization()
        ! New criterion
        call criterion_localization(tmp_list_size, tmp_list, criterion)
        print*,'Criterion:', trim(mo_class(tmp_list(1))), nb_iter, criterion
        print*,'Max elem :', max_elem
        print*,'Delta    :', delta
        nb_iter = nb_iter + 1
        ! Exit
        if (nb_iter >= localization_max_nb_iter .or. dabs(max_elem) < thresh_loc_max_elem_grad) then
           not_converged = .False.
        endif
      enddo
      ! Save the changes
      call update_data_localization()
      call save_mos()
      TOUCH mo_coef
      ! Deallocate
      deallocate(v_grad, tmp_m_x, tmp_list)
      deallocate(tmp_R, tmp_x)
    ! Trust region
    else
      ! Allocation of temporary arrays
      allocate(v_grad(tmp_n), H(tmp_n), tmp_m_x(tmp_list_size, tmp_list_size))
      allocate(tmp_R(tmp_list_size, tmp_list_size))
      allocate(tmp_x(tmp_n), W(tmp_n), e_val(tmp_n), key(tmp_n))
      ! ### Initialization ###
      delta = 0d0 ! can be deleted (normally)
      nb_iter = 0 ! Must start at 0 !!!
      rho = 0.5d0 ! Must be 0.5
      ! Compute the criterion before the loop
      call criterion_localization(tmp_list_size, tmp_list, prev_criterion)
      ! Loop until the convergence
      do while (not_converged)
        print*,''
        print*,'***********************'
        print*,'Iteration', nb_iter
        print*,'***********************'
        print*,''
        ! Gradient
        call gradient_localization(tmp_n, tmp_list_size, tmp_list, v_grad, max_elem, norm_grad)
        ! Diagonal hessian
        call hessian_localization(tmp_n, tmp_list_size, tmp_list, H)
        ! Diagonalization of the diagonal hessian by hands
        !call diagonalization_hessian(tmp_n,H,e_val,w)
        do i = 1, tmp_n
          e_val(i) = H(i)
        enddo
        ! Key list for dsort
        do i = 1, tmp_n 
          key(i) = i
        enddo
        ! Sort of the eigenvalues
        call dsort(e_val, key, tmp_n)
        ! Eigenvectors
        W = 0d0
        do i = 1, tmp_n
          W(i) = dble(key(i))
        enddo
        ! To enter in the loop just after
        cancel_step = .True.
        nb_sub_iter = 0 
        ! Loop to reduce the trust radius until the criterion decreases and rho >= thresh_rho
        do while (cancel_step)
          print*,'-----------------------------'
          print*, mo_class(tmp_list(1))
          print*,'Iteration:', nb_iter
          print*,'Sub iteration:', nb_sub_iter
          print*,'Max elem grad:', max_elem
          print*,'-----------------------------'
          ! Hessian,gradient,Criterion -> x 
          call trust_region_step_w_expected_e(tmp_n,1, H, W, e_val, v_grad, prev_criterion, &
               rho, nb_iter, delta, criterion_model, tmp_x, must_exit)
          ! Internal loop exit condition
          if (must_exit) then
            print*,'trust_region_step_w_expected_e sent: Exit'
            exit 
          endif
          ! 1D tmp -> 2D tmp 
          call vec_to_mat_v2(tmp_n, tmp_list_size, tmp_x, tmp_m_x)
          ! Rotation submatrix (square matrix tmp_list_size by tmp_list_size)
          call rotation_matrix(tmp_m_x, tmp_list_size, tmp_R, tmp_list_size, tmp_list_size, &
               info, enforce_step_cancellation)
          if (enforce_step_cancellation) then
            print*, 'Step cancellation, too large error in the rotation matrix'
            rho = 0d0
            cycle
          endif
          ! tmp_R to R, subspace to full space
          call sub_to_full_rotation_matrix(tmp_list_size, tmp_list, tmp_R, R)
          ! Rotation of the MOs
          call apply_mo_rotation(R, prev_mos)   
          ! Update the things related to mo_coef
          call update_data_localization()
          ! Update the criterion
          call criterion_localization(tmp_list_size, tmp_list, criterion)
          print*,'Criterion:', trim(mo_class(tmp_list(1))), nb_iter, criterion
          ! Criterion -> step accepted or rejected 
          call trust_region_is_step_cancelled(nb_iter, prev_criterion, criterion, &
               criterion_model, rho, cancel_step)
          ! Cancellation of the step, previous MOs
          if (cancel_step) then
            mo_coef = prev_mos
          endif
          nb_sub_iter = nb_sub_iter + 1
        enddo
        !call save_mos() !### depend of the time for 1 iteration
        ! To exit the external loop if must_exti = .True.
        if (must_exit) then
          exit
        endif 
        ! Step accepted, nb iteration + 1
        nb_iter = nb_iter + 1
        ! External loop exit conditions
        if (DABS(max_elem) < thresh_loc_max_elem_grad) then
          not_converged = .False.
        endif
        if (nb_iter > localization_max_nb_iter) then
          not_converged = .False.
        endif
      enddo
      ! Deallocation of temporary arrays
      deallocate(v_grad, H, tmp_m_x, tmp_R, tmp_list, tmp_x, W, e_val, key)
      ! Save the MOs
      call save_mos()
      TOUCH mo_coef
      ! Debug
      if (debug_hf) then
        touch mo_coef
        print*,'HF energy:', HF_energy
      endif
    endif
  enddo
  ! Seems unecessary
  TOUCH mo_coef 
  ! To sort the MOs using the diagonal elements of the Fock matrix
  if (sort_mos_by_e) then
    call run_sort_by_fock_energies()
  endif
  ! Debug
  if (debug_hf) then
    touch mo_coef
    print*,'HF energy:', HF_energy
  endif
  ! Locality after the localization
  call compute_spatial_extent(spatial_extent)
 end
--- a/src/mo_localization/localization_sub.irp.f
+++ b/src/mo_localization/localization_sub.irp.f
--- a/src/mo_localization/org/TANGLE_org_mode.sh
+++ b/src/mo_localization/org/TANGLE_org_mode.sh
@ -0,0 +1,7 @@
 #!/bin/sh   
 list='ls *.org'
 for element in $list    
 do   
 		emacs --batch $element -f org-babel-tangle
 done
--- a/src/mo_localization/org/break_spatial_sym.org
+++ b/src/mo_localization/org/break_spatial_sym.org
@ -0,0 +1,28 @@
 ! A small program to break the spatial symmetry of the MOs.
 ! You have to defined your MO classes or set security_mo_class to false
 ! with:
 ! qp set orbital_optimization security_mo_class false
 ! The default angle for the rotations is too big for this kind of
 ! application, a value between 1e-3 and 1e-6 should break the spatial
 ! symmetry with just a small change in the energy. 
 #+BEGIN_SRC f90 :comments org :tangle break_spatial_sym.irp.f
 program break_spatial_sym
  !BEGIN_DOC
  ! Break the symmetry of the MOs with a rotation
  !END_DOC
  implicit none
  kick_in_mos = .True.
  TOUCH kick_in_mos
  call set_classes_loc 
  call apply_pre_rotation
  call unset_classes_loc 
 end
 #+END_SRC
--- a/src/mo_localization/org/debug_gradient_loc.org
+++ b/src/mo_localization/org/debug_gradient_loc.org
@ -0,0 +1,67 @@
 #+BEGIN_SRC f90 :comments org :tangle debug_gradient_loc.irp.f
 program debug_gradient_loc
  !BEGIN_DOC
  ! Check if the gradient is correct
  !END_DOC
  implicit none
  integer :: list_size, n
  integer, allocatable :: list(:)
  double precision, allocatable :: v_grad(:), v_grad2(:)
  double precision :: norm, max_elem, threshold, max_error
  integer :: i, nb_error
  threshold = 1d-12
  list_size = dim_list_act_orb
  allocate(list(list_size))
  list = list_act
  n = list_size*(list_size-1)/2
  allocate(v_grad(n),v_grad2(n))
  if (localization_method == 'boys') then
    print*,'Foster-Boys'
    call gradient_FB(n,list_size,list,v_grad,max_elem,norm)
    call gradient_FB_omp(n,list_size,list,v_grad2,max_elem,norm)
  elseif (localization_method == 'pipek') then
    print*,'Pipek-Mezey'
    call gradient_PM(n,list_size,list,v_grad,max_elem,norm)
    call gradient_PM(n,list_size,list,v_grad2,max_elem,norm) 
  else
    print*,'Unknown localization_method, please select boys or pipek'
    call abort
  endif
  do i = 1, n
    print*,i,v_grad(i)
  enddo
  v_grad = v_grad - v_grad2
  nb_error = 0
  max_elem = 0d0
  do i = 1, n
    if (dabs(v_grad(i)) > threshold) then
      print*,v_grad(i)
      nb_error = nb_error + 1
      if (dabs(v_grad(i)) > max_elem) then
        max_elem = v_grad(i)
      endif
    endif
  enddo
  print*,'Threshold error', threshold
  print*, 'Nb error', nb_error
  print*,'Max error', max_elem
  deallocate(v_grad,v_grad2)
 end
 #+END_SRC
--- a/src/mo_localization/org/debug_hessian_loc.org
+++ b/src/mo_localization/org/debug_hessian_loc.org
@ -0,0 +1,67 @@
 #+BEGIN_SRC f90 :comments org :tangle debug_hessian_loc.irp.f
 program debug_hessian_loc
  !BEGIN_DOC
  ! Check if the hessian is correct
  !END_DOC
  implicit none
  integer :: list_size, n
  integer, allocatable :: list(:)
  double precision, allocatable :: H(:), H2(:)
  double precision :: threshold, max_error, max_elem
  integer :: i, nb_error
  threshold = 1d-12
  list_size = dim_list_act_orb
  allocate(list(list_size))
  list = list_act
  n = list_size*(list_size-1)/2
  allocate(H(n),H2(n))
  if (localization_method == 'boys') then
    print*,'Foster-Boys'
    call hessian_FB(n,list_size,list,H)
    call hessian_FB_omp(n,list_size,list,H2)
  elseif(localization_method == 'pipek') then
    print*,'Pipek-Mezey'
    call hessian_PM(n,list_size,list,H)
    call hessian_PM(n,list_size,list,H2)
  else
    print*,'Unknown localization_method, please select boys or pipek'
    call abort
  endif
  do i = 1, n
    print*,i,H(i)
  enddo
  H = H - H2
  nb_error = 0
  max_elem = 0d0
  do i = 1, n
    if (dabs(H(i)) > threshold) then
      print*,H(i)
      nb_error = nb_error + 1
      if (dabs(H(i)) > max_elem) then
        max_elem = H(i)
      endif
    endif
  enddo
  print*,'Threshold error', threshold
  print*, 'Nb error', nb_error
  print*,'Max error', max_elem
  deallocate(H,H2)
 end
 #+END_SRC
--- a/src/mo_localization/org/kick_the_mos.org
+++ b/src/mo_localization/org/kick_the_mos.org
@ -0,0 +1,18 @@
 #+BEGIN_SRC f90 :comments org :tangle kick_the_mos.irp.f
 program kick_the_mos
  !BEGIN_DOC
  ! To do a small rotation of the MOs
  !END_DOC
  implicit none
  kick_in_mos = .True.
  TOUCH kick_in_mos
  call set_classes_loc
  call apply_pre_rotation
  call unset_classes_loc
 end
 #+END_SRC
--- a/src/mo_localization/org/localization.org
+++ b/src/mo_localization/org/localization.org