qp_plugins_scemama/devel/svdwf/printSQ_ij_T_kl.irp.f

program printSQ_ij_T_kl

  implicit none

  BEGIN_DOC
  ! perturbative approach to build psi_postsvd
  END_DOC

  read_wf = .True.
  TOUCH read_wf

  PROVIDE N_int

  call run()
end


subroutine run

  USE OMP_LIB
  USE bitmasks

  implicit none

  integer(bit_kind)             :: det1(N_int,2), det2(N_int,2)
  integer                       :: degree, i_state
  double precision              :: h12

  integer                       :: i, j, k, l
  double precision, allocatable :: T(:,:,:,:)

  double precision              :: ti, tf
  integer                       :: nb_taches

  !$OMP PARALLEL
  nb_taches = OMP_GET_NUM_THREADS()
  !$OMP END PARALLEL

  call wall_time(ti)

  i_state = 1

  det1(:,1) = psi_det_alpha_unique(:,1)
  det2(:,1) = psi_det_alpha_unique(:,1)
  det1(:,2) = psi_det_beta_unique(:,1)
  det2(:,2) = psi_det_beta_unique(:,1)
  call get_excitation_degree_spin(det1(1,1),det2(1,1),degree,N_int)
  call get_excitation_degree(det1,det2,degree,N_int)
  call i_H_j(det1, det2, N_int, h12)


  ! ---------------------------------------------------------------------------------------
  !                      construct the initial CI matrix

  print *, ' ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~'
  print *, ' CI matrix :', n_det_alpha_unique,'x',n_det_beta_unique
  print *, ' N det     :', N_det
  print *, ' ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~ ~'

  ! ---------------------------------------------------------------------------------------
  ! ---------------------------------------------------------------------------------------


  allocate( T(n_det_alpha_unique,n_det_beta_unique,n_det_alpha_unique,n_det_beta_unique) )
  call const_2b(T)

  open(UNIT=11, FILE="ij_T_kl.dat", ACTION="WRITE")
    do i = 1, n_det_alpha_unique
      do j = 1, n_det_beta_unique
        do k = 1, n_det_alpha_unique
          do l = 1, n_det_beta_unique
            write(11, '(E15.7)') T(i,j,k,l)
            !write(11, '(4(I5,2X), 5X, E15.7)') i, j, k, l, T(i,j,k,l)
          enddo
        enddo
      enddo
    enddo
  close(11)

  deallocate( T )

  call wall_time(tf)

  print *, ' ___________________________________________________________________'
  print *, ' '
  !print *, " Execution avec ", nb_taches, " threads"
  print *, " Execution avec 1 threads"
  print *, " total elapsed time (min) = ", (tf-ti)/60.d0
  print *, ' ___________________________________________________________________'


end



  !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!
  !---!     !---!     !---!     !---!     !---!     !---!     !---!     !---!     !---! 
  ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !
  !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!
  !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!

  !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!
  !---!     !---!     !---!     !---!     !---!     !---!     !---!     !---!     !---! 
  ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !
  !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!
  !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!

  !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!
  !---!     !---!     !---!     !---!     !---!     !---!     !---!     !---!     !---! 
  ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !
  !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!
  !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!

  !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!     !/-\!
  !---!     !---!     !---!     !---!     !---!     !---!     !---!     !---!     !---! 
  ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !     ! ! !
  !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!
  !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!     !___!




subroutine const_2b(T)

  USE bitmasks
  implicit none

  double precision, external    :: get_two_e_integral

  double precision, intent(out) :: T(n_det_alpha_unique,n_det_beta_unique,n_det_alpha_unique,n_det_beta_unique )

  integer                       :: na, nb
  integer                       :: i, k, j, l

  integer(bit_kind)             :: psi_ij(N_int,2), psi_kl(N_int,2)
  double precision              :: phase
  integer                       :: degree, h1, h2, p1, p2, s1, s2, e1, e2
  integer                       :: ii, jj
  integer                       :: exc(0:2,2,2)

  integer                       :: occ(N_int*bit_kind_size,2), n_occ_alpha

  double precision              :: two_body_fact

  na = n_det_alpha_unique
  nb = n_det_beta_unique
  
  T(:,:,:,:) = 0.d0

  ! -----------------------------------------------------------------------------------------------------------------
  do i = 1, na
    psi_ij(1:N_int,1) = psi_det_alpha_unique(1:N_int,i)
    do j = 1, nb
      psi_ij(1:N_int,2) = psi_det_beta_unique(1:N_int,j)

      call bitstring_to_list(psi_ij(1,1), occ(1,1), n_occ_alpha, N_int)
      call bitstring_to_list(psi_ij(1,2), occ(1,2), n_occ_alpha, N_int)

      do k = 1, na
        psi_kl(1:N_int,1) = psi_det_alpha_unique(1:N_int,k)
        do l = 1, nb
          psi_kl(1:N_int,2) = psi_det_beta_unique(1:N_int,l)

          call get_excitation_degree(psi_ij, psi_kl, degree, N_int)

          two_body_fact = 0.d0

          if(degree .eq. 2) then

            call get_double_excitation(psi_ij, psi_kl, exc, phase, N_int)
            call decode_exc(exc, degree, h1, p1, h2, p2, s1, s2)

            select case(s1+s2)
              case(2,4)
                two_body_fact += phase * get_two_e_integral(h1, h2, p1, p2, mo_integrals_map)
                two_body_fact -= phase * get_two_e_integral(h1, h2, p2, p1, mo_integrals_map)
              case(3) 
                two_body_fact += 0.5d0 * phase * get_two_e_integral(h1, h2, p1, p2, mo_integrals_map)
                two_body_fact += 0.5d0 * phase * get_two_e_integral(h2, h1, p2, p1, mo_integrals_map)
            end select

          else if(degree .eq. 1) then

            call get_single_excitation(psi_ij, psi_kl, exc, phase, N_int)
            call decode_exc(exc, degree, h1, p1, h2, p2, s1, s2)

            select case(s1)
              case(1)
                do ii = 1, elec_alpha_num
                  p2 = occ(ii,1)
                  h2 = p2
                  two_body_fact += 0.5d0 * phase * get_two_e_integral(h1, h2, p1, p2, mo_integrals_map) 
                  two_body_fact -= 0.5d0 * phase * get_two_e_integral(h1, h2, p2, p1, mo_integrals_map) 
                  two_body_fact += 0.5d0 * phase * get_two_e_integral(h2, h1, p2, p1, mo_integrals_map) 
                  two_body_fact -= 0.5d0 * phase * get_two_e_integral(h2, h1, p1, p2, mo_integrals_map)
                enddo
                do ii = 1, elec_beta_num
                  p2 = occ(ii,2)
                  h2 = p2
                  two_body_fact += 0.5d0 * phase * get_two_e_integral(h1, h2, p1, p2, mo_integrals_map) 
                  two_body_fact += 0.5d0 * phase * get_two_e_integral(h2, h1, p2, p1, mo_integrals_map)
                enddo
              case(2)
                do ii = 1, elec_alpha_num
                  p2 = occ(ii,1)
                  h2 = p2
                  two_body_fact += 0.5d0 * phase * get_two_e_integral(h1, h2, p1, p2, mo_integrals_map)
                  two_body_fact += 0.5d0 * phase * get_two_e_integral(h2, h1, p2, p1, mo_integrals_map)
                enddo
                do ii = 1, elec_beta_num
                  p2 = occ(ii,2)
                  h2 = p2
                  two_body_fact += 0.5d0 * phase * get_two_e_integral(h1, h2, p1, p2, mo_integrals_map) 
                  two_body_fact -= 0.5d0 * phase * get_two_e_integral(h1, h2, p2, p1, mo_integrals_map) 
                  two_body_fact += 0.5d0 * phase * get_two_e_integral(h2, h1, p2, p1, mo_integrals_map) 
                  two_body_fact -= 0.5d0 * phase * get_two_e_integral(h2, h1, p1, p2, mo_integrals_map) 
                enddo
            end select

          else if(degree .eq. 0) then

            do ii = 1, elec_alpha_num
              e1 = occ(ii,1)
              do jj = 1, elec_alpha_num
                e2 = occ(jj,1)
                two_body_fact += 0.5d0 * get_two_e_integral(e1, e2, e1, e2, mo_integrals_map)
                two_body_fact -= 0.5d0 * get_two_e_integral(e1, e2, e2, e1, mo_integrals_map)
              enddo
              do jj = 1, elec_beta_num
                e2 = occ(jj,2)
                two_body_fact += 0.5d0 * get_two_e_integral(e1, e2, e1, e2, mo_integrals_map)
                two_body_fact += 0.5d0 * get_two_e_integral(e2, e1, e2, e1, mo_integrals_map)
              enddo
            enddo
            do ii = 1, elec_beta_num
              e1 = occ(ii,2)
              do jj = 1, elec_beta_num
                e2 = occ(jj,2)
                two_body_fact += 0.5d0 * get_two_e_integral(e1, e2, e1, e2, mo_integrals_map)
                two_body_fact -= 0.5d0 * get_two_e_integral(e1, e2, e2, e1, mo_integrals_map)
              enddo
            enddo

          end if

          T(i,j,k,l) = two_body_fact
        enddo
      enddo
    enddo
  enddo
  ! -----------------------------------------------------------------------------------------------------------------

  return
end subroutine const_2b