working on casscf_cipsi

2024-12-21 11:03:29 +01:00 · 2023-10-06 11:28:20 +02:00 · 2023-10-06 11:28:20 +02:00 · 2b62bfc999
commit 2b62bfc999
parent dbd0f16307
8 changed files with 153 additions and 27 deletions
--- a/src/casscf_cipsi/EZFIO.cfg
+++ b/src/casscf_cipsi/EZFIO.cfg
@ -73,3 +73,9 @@ type: logical
 doc: If |true|, the pt2_max value in the CIPSI iterations will automatically adapt, otherwise it is fixed at the value given in the EZFIO folder
 interface: ezfio,provider,ocaml
 default: True
+
+[small_active_space]
+type: logical
+doc: If |true|, the pt2_max value in the CIPSI is set to 10-10 and will not change
+interface: ezfio,provider,ocaml
+default: False
--- a/src/casscf_cipsi/README.rst
+++ b/src/casscf_cipsi/README.rst
@ -3,3 +3,39 @@ casscf
 ======

 |CASSCF| program with the CIPSI algorithm.
+
+Example of inputs
+-----------------
+
+a) Small active space : standard CASSCF 
+---------------------------------------
+Let's do O2 (triplet) in aug-cc-pvdz with the following geometry (xyz format, Bohr units)
+3
+
+ O           0.0000000000        0.0000000000       -1.1408000000
+ O           0.0000000000        0.0000000000        1.1408000000
+
+# Create the ezfio folder 
+qp create_ezfio -b aug-cc-pvdz O2.xyz -m 3 -a -o O2_avdz
+
+# Start with an ROHF guess 
+qp run scf | tee ${EZFIO_FILE}.rohf.out
+
+# Get the ROHF energy for check 
+qp get hartree_fock energy # should be -149.4684509
+
+# Define the full valence active space: the two 1s are doubly occupied, the other 8 valence orbitals are active 
+# CASSCF(12e,10orb) 
+qp set_mo_class -c "[1-2]" -a "[3-10]" -v "[11-46]"
+
+# Specify that you want an near exact CASSCF, i.e. the CIPSI selection will stop at pt2_max = 10^-10
+qp set casscf_cipsi small_active_space True 
+# RUN THE CASSCF 
+qp run casscf | tee ${EZFIO_FILE}.casscf.out
+
+
+b) Large active space : Exploit the selected CI in the active space 
+-------------------------------------------------------------------
+Let us start from the small active space calculation orbitals and add another shell of 
+
+
--- a/src/casscf_cipsi/casscf.irp.f
+++ b/src/casscf_cipsi/casscf.irp.f
@ -8,17 +8,22 @@ program casscf
 !  touch no_vvvv_integrals
  n_det_max_full = 500
  touch n_det_max_full
+  if(small_active_space)then
+   pt2_relative_error = 0.00001
+  else
   pt2_relative_error = 0.04
+  endif
  touch pt2_relative_error 
-!  call run_stochastic_cipsi
  call run
 end

 subroutine run
  implicit none
-  double precision               :: energy_old, energy, pt2_max_before, ept2_before,delta_E
+  double precision               :: energy_old, energy, pt2_max_before,delta_E
  logical                        :: converged,state_following_casscf_cipsi_save
-  integer                        :: iteration
+  integer                        :: iteration,istate
+  double precision, allocatable :: E_PT2(:), PT2(:), Ev(:), ept2_before(:)
+  allocate(E_PT2(N_states), PT2(N_states), Ev(N_states), ept2_before(N_states))
  converged = .False.

  energy = 0.d0
@ -28,13 +33,19 @@ subroutine run
  state_following_casscf = .True.
  touch state_following_casscf
  ept2_before = 0.d0
+  if(small_active_space)then
+   pt2_max = 1.d-10
+   SOFT_TOUCH pt2_max
+  else
   if(adaptive_pt2_max)then
    pt2_max = 0.005
    SOFT_TOUCH pt2_max
   endif
+  endif
  do while (.not.converged)
    print*,'pt2_max = ',pt2_max
-    call run_stochastic_cipsi
+    call run_stochastic_cipsi(Ev,PT2)
+    E_PT2(1:N_states) = Ev(1:N_states) + PT2(1:N_states)
    energy_old = energy
    energy = eone+etwo+ecore
    pt2_max_before = pt2_max
@ -42,15 +53,13 @@ subroutine run
    call write_time(6)
    call write_int(6,iteration,'CAS-SCF iteration = ')
    call write_double(6,energy,'CAS-SCF energy = ')
-    if(n_states == 1)then
-     double precision :: E_PT2, PT2
-     call ezfio_get_casscf_cipsi_energy_pt2(E_PT2)
-     call ezfio_get_casscf_cipsi_energy(PT2)
-     PT2 -= E_PT2
-     call write_double(6,E_PT2,'E + PT2 energy = ')
-     call write_double(6,PT2,'  PT2          = ')
+!    if(n_states == 1)then
+!     call ezfio_get_casscf_cipsi_energy_pt2(E_PT2)
+!     call ezfio_get_casscf_cipsi_energy(PT2)
+     call write_double(6,E_PT2(1:N_states),'E + PT2 energy = ')
+     call write_double(6,PT2(1:N_states),'  PT2          = ')
     call write_double(6,pt2_max,' PT2_MAX       = ')
-    endif
+!    endif

    print*,''
    call write_double(6,norm_grad_vec2,'Norm of gradients = ')
@ -65,10 +74,14 @@ subroutine run
    else if (criterion_casscf == "gradients")then
     converged = norm_grad_vec2 < thresh_scf
    else if (criterion_casscf == "e_pt2")then
-     delta_E = dabs(E_PT2 - ept2_before)
+     delta_E = 0.d0
+     do istate = 1, N_states
+      delta_E += dabs(E_PT2(istate) - ept2_before(istate))
+     enddo
     converged = dabs(delta_E) < thresh_casscf
    endif
    ept2_before = E_PT2
+    if(.not.small_active_space)then
     if(adaptive_pt2_max)then
      pt2_max = dabs(energy_improvement / (pt2_relative_error))
      pt2_max = min(pt2_max, pt2_max_before)
@ -76,6 +89,7 @@ subroutine run
       pt2_max = max(pt2_max,pt2_min_casscf)
      endif
     endif
+    endif
    print*,''
    call write_double(6,pt2_max, 'PT2_MAX for next iteration = ')

@ -94,9 +108,11 @@ subroutine run
     read_wf = .True.
     call clear_mo_map
     SOFT_TOUCH mo_coef N_det psi_det psi_coef
+     if(.not.small_active_space)then
      if(adaptive_pt2_max)then
        SOFT_TOUCH pt2_max  
      endif
+     endif
     if(iteration .gt. 3)then
      state_following_casscf = state_following_casscf_cipsi_save
      soft_touch state_following_casscf
@ -104,6 +120,27 @@ subroutine run
    endif

  enddo
+     integer :: i
+!    print*,'Converged CASSCF '
+!    print*,'--------------------------'
+!    write(6,*) ' occupation numbers of orbitals '
+!    do i=1,mo_num
+!      write(6,*) i,occnum(i)
+!    end do
+!
+!     write(6,*)
+!     write(6,*) ' the diagonal of the inactive effective Fock matrix '
+!     write(6,'(5(i3,F12.5))') (i,Fipq(i,i),i=1,mo_num)
+!     write(6,*)
+  print*,'Fock ROHF '
+  do i = 1, ao_num
+   write(33,*)fock_matrix_ao_alpha(i,1:ao_num)
+  enddo
+  print*,'Fock MCSCF'
+  do i = 1, ao_num
+   write(34,*)mcscf_fock_alpha(i,1:ao_num)
+  enddo
+

 end

--- a/src/casscf_cipsi/densities.irp.f
+++ b/src/casscf_cipsi/densities.irp.f
@ -15,6 +15,35 @@ BEGIN_PROVIDER [real*8, D0tu, (n_act_orb,n_act_orb) ]
    enddo
  enddo
  
+END_PROVIDER
+
+ BEGIN_PROVIDER [double precision, D0tu_alpha_ao, (ao_num, ao_num)]
+&BEGIN_PROVIDER [double precision, D0tu_beta_ao, (ao_num, ao_num)]
+ implicit none
+ integer :: i,ii,j,u,t,uu,tt
+ double precision, allocatable :: D0_tmp_alpha(:,:),D0_tmp_beta(:,:)
+ allocate(D0_tmp_alpha(mo_num, mo_num),D0_tmp_beta(mo_num, mo_num))
+ D0_tmp_beta = 0.d0
+ D0_tmp_alpha = 0.d0
+ do i = 1, n_core_inact_orb
+  ii = list_core_inact(i)
+  D0_tmp_alpha(ii,ii) = 1.d0
+  D0_tmp_beta(ii,ii) = 1.d0
+ enddo
+ print*,'Diagonal elements of the 1RDM in the active space'
+ do u=1,n_act_orb
+   uu = list_act(u)
+   print*,uu,one_e_dm_mo_alpha_average(uu,uu),one_e_dm_mo_beta_average(uu,uu)
+   do t=1,n_act_orb
+    tt = list_act(t)
+    D0_tmp_alpha(tt,uu) = one_e_dm_mo_alpha_average(tt,uu)
+    D0_tmp_beta(tt,uu) = one_e_dm_mo_beta_average(tt,uu)
+   enddo
+ enddo
+
+ call mo_to_ao_no_overlap(D0_tmp_alpha,mo_num,D0tu_alpha_ao,ao_num)
+ call mo_to_ao_no_overlap(D0_tmp_beta,mo_num,D0tu_beta_ao,ao_num)
+
 END_PROVIDER 

 BEGIN_PROVIDER [real*8, P0tuvx, (n_act_orb,n_act_orb,n_act_orb,n_act_orb) ]
--- a/src/casscf_cipsi/mcscf_fock.irp.f
+++ b/src/casscf_cipsi/mcscf_fock.irp.f
@ -77,4 +77,15 @@ BEGIN_PROVIDER [real*8, Fapq, (mo_num,mo_num) ]
   
 END_PROVIDER
 
- 
+ BEGIN_PROVIDER [ double precision, mcscf_fock_alpha, (ao_num, ao_num)] 
+&BEGIN_PROVIDER [ double precision, mcscf_fock_beta, (ao_num, ao_num)] 
+ implicit none
+ BEGIN_DOC
+  ! mcscf_fock_alpha are set to usual Fock like operator but computed with the MCSCF densities 
+ END_DOC
+ SCF_density_matrix_ao_alpha = D0tu_alpha_ao
+ SCF_density_matrix_ao_beta = D0tu_beta_ao
+ soft_touch SCF_density_matrix_ao_alpha SCF_density_matrix_ao_beta 
+ mcscf_fock_beta = fock_matrix_ao_beta
+ mcscf_fock_alpha = fock_matrix_ao_alpha
+END_PROVIDER 
--- a/src/cipsi/stochastic_cipsi.irp.f
+++ b/src/cipsi/stochastic_cipsi.irp.f
@ -1,10 +1,11 @@
-subroutine run_stochastic_cipsi
+subroutine run_stochastic_cipsi(Ev,PT2) 
  use selection_types
  implicit none
  BEGIN_DOC
 ! Selected Full Configuration Interaction with Stochastic selection and PT2.
  END_DOC
  integer                        :: i,j,k
+  double precision, intent(out)  :: Ev(N_states), PT2(N_states) 
  double precision, allocatable  :: zeros(:)
  integer                        :: to_select
  type(pt2_type)                 :: pt2_data, pt2_data_err
@ -139,6 +140,8 @@ subroutine run_stochastic_cipsi
    call print_mol_properties()
    call write_cipsi_json(pt2_data,pt2_data_err)
  endif
+  Ev(1:N_states) = psi_energy_with_nucl_rep(1:N_states)
+  PT2(1:N_states) = pt2_data % pt2(1:N_states)
  call pt2_dealloc(pt2_data)
  call pt2_dealloc(pt2_data_err)

--- a/src/fci/fci.irp.f
+++ b/src/fci/fci.irp.f
@ -41,8 +41,10 @@ program fci

    write(json_unit,json_array_open_fmt) 'fci'

+    double precision, allocatable :: Ev(:),PT2(:)
+    allocate(Ev(N_states), PT2(N_state))
    if (do_pt2) then
-      call run_stochastic_cipsi
+      call run_stochastic_cipsi(Ev,PT2)
    else
      call run_cipsi
    endif
--- a/src/mo_optimization/cipsi_orb_opt.irp.f
+++ b/src/mo_optimization/cipsi_orb_opt.irp.f
@ -11,11 +11,13 @@ subroutine run_optimization
  implicit none

  double precision :: e_cipsi, e_opt, delta_e
+  double precision, allocatable :: Ev(:),PT2(:)
  integer :: nb_iter,i
  logical :: not_converged
  character (len=100) :: filename

  PROVIDE psi_det psi_coef mo_two_e_integrals_in_map ao_pseudo_integrals
+  allocate(Ev(N_states),PT2(N_states))

  not_converged = .True.
  nb_iter = 0
@ -38,7 +40,7 @@ subroutine run_optimization
      print*,'' 
      print*,'********** cipsi step **********'
      ! cispi calculation
-      call run_stochastic_cipsi
+      call run_stochastic_cipsi(Ev,PT2)

      ! State average energy after the cipsi step
      call state_average_energy(e_cipsi)