Delete mo_energy_expval.irp.broken

src/determinants/mo_energy_expval.irp.broken

@@ -1,160 +0,0 @@
-BEGIN_PROVIDER [ double precision, mo_energy_expval, (N_states,mo_num,2,2)]
-  use bitmasks
-  implicit none
-  BEGIN_DOC
-  ! Third index is spin.
-  ! Fourth index is 1:creation, 2:annihilation
-  END_DOC
-  integer                        :: i,j,k
-  integer                        :: ispin, istate
-  integer                        :: hp
-  double precision               :: norm_out(N_states)
-
-  integer, parameter             :: hole_particle(2) = (/ -1, 1 /)
-  double precision               :: energies(n_states)
-
-  integer(bit_kind), allocatable :: psi_in_out(:,:,:)
-  double precision, allocatable  :: psi_in_out_coef(:,:)
-  double precision               :: E0(N_states), norm
-  double precision, parameter    :: t=1.d-3
-
-  allocate (psi_in_out(N_int,2,N_det),psi_in_out_coef(N_det,N_states))
-  mo_energy_expval = 0.d0
-
-  psi_in_out_coef(1:N_det,1:N_states) = psi_coef(1:N_det,1:N_states)
-  psi_in_out(1:N_int,1:2,1:N_det) = psi_det(1:N_int,1:2,1:N_det)
-
-  ! Truncate the wave function
-  do istate=1,N_states
-    norm = 0.d0
-    do k=1,N_det
-      if (dabs(psi_in_out_coef(k,istate)) < t) then
-        psi_in_out_coef(k,istate) = 0.d0
-      endif
-      norm = norm + psi_in_out_coef(k,istate)*psi_in_out_coef(k,istate)
-    enddo
-    ASSERT (norm  > 0.d0)
-    norm = 1.d0/dsqrt(norm)
-    psi_in_out_coef(1:N_det,istate) = psi_in_out_coef(1:N_det,istate) * norm
-    call au0_h_au0(E0,psi_in_out,psi_in_out_coef,N_det,size(psi_in_out_coef,1))
-  enddo
-
-
-  do hp=1,2
-    do ispin=1,2
-      do i=1,mo_num
-        psi_in_out_coef(1:N_det,1:N_states) = psi_coef(1:N_det,1:N_states)
-        psi_in_out(1:N_int,1:2,1:N_det) = psi_det(1:N_int,1:2,1:N_det)
-        call apply_exc_to_psi(i,hole_particle(hp),ispin,             &
-            norm_out,psi_in_out,psi_in_out_coef, N_det,N_det,N_det,N_states)
-
-        ! Truncate the wave function
-        do istate=1,N_states
-          norm = 0.d0
-          do k=1,N_det
-            if (dabs(psi_in_out_coef(k,istate)) < t) then
-              psi_in_out_coef(k,istate) = 0.d0
-            endif
-            norm = norm + psi_in_out_coef(k,istate)*psi_in_out_coef(k,istate)
-          enddo
-          if (norm == 0.d0) then
-            cycle
-          endif
-          norm = 1.d0/dsqrt(norm)
-          psi_in_out_coef(1:N_det,istate) = psi_in_out_coef(1:N_det,istate) * norm
-        enddo
-        call au0_h_au0(energies,psi_in_out,psi_in_out_coef,N_det,size(psi_in_out_coef,1))
-        mo_energy_expval(1:N_states,i,ispin,hp) = energies(1:N_states) - E0(1:N_states)
-        print *,  i, ispin, real(energies(1)), real(E0(1))
-      enddo
-    enddo
-
-  enddo
-  mo_energy_expval(1:N_states,1:mo_num,1:2,1) = -mo_energy_expval(1:N_states,1:mo_num,1:2,1)
-
-END_PROVIDER
-
-
-subroutine au0_h_au0(energies,psi_in,psi_in_coef,ndet,dim_psi_coef)
-  use bitmasks
-  implicit none
-  integer, intent(in)            :: ndet,dim_psi_coef
-  integer(bit_kind), intent(in)  :: psi_in(N_int,2,Ndet)
-  double precision,  intent(in)  :: psi_in_coef(dim_psi_coef,N_states)
-  double precision,  intent(out) :: energies(N_states)
-
-  integer                        :: i,j, istate
-  double precision               :: hij,accu
-  double precision, allocatable  :: psi_coef_tmp(:)
-
-  energies(1:N_states) = 0.d0
-  do i = 1, Ndet
-    if(sum(dabs(psi_in_coef(i,1:N_states)))==0.d0) then
-      cycle
-    endif
-    call diag_H_mat_elem_au0_h_au0(psi_in(1,1,i),N_int,hij)
-    do istate=1,N_states
-      energies(istate) += psi_in_coef(i,istate) * psi_in_coef(i,istate) * hij
-    enddo
-    do j = i+1, Ndet
-      if(sum(dabs(psi_in_coef(j,1:N_states)))==0.d0) then
-        cycle
-      endif
-      call i_H_j(psi_in(1,1,i),psi_in(1,1,j),N_int,hij)
-      hij = hij+hij
-      do istate=1,N_states
-        energies(istate) = energies(istate) + psi_in_coef(i,istate) * psi_in_coef(j,istate) * hij
-      enddo
-    enddo
-  enddo
-end
-
-subroutine diag_H_mat_elem_au0_h_au0(det_in,Nint,hii)
-  use bitmasks
-  implicit none
-  BEGIN_DOC
-  ! Computes $\langle i|H|i \rangle$ for any determinant $|i\rangle$.
-  ! Used for wave functions with an additional electron.
-  END_DOC
-  integer,intent(in)             :: Nint
-  integer(bit_kind),intent(in)   :: det_in(Nint,2)
-  double precision, intent(out)  :: hii
-
-  integer                        :: i, j, iorb, jorb
-  integer                        :: occ(Nint*bit_kind_size,2)
-  integer                        :: elec_num_tab_local(2)
-
-  hii = 0.d0
-  call bitstring_to_list(det_in(1,1), occ(1,1), elec_num_tab_local(1), Nint)
-  call bitstring_to_list(det_in(1,2), occ(1,2), elec_num_tab_local(2), Nint)
-
-  ! alpha - alpha
-  do i = 1, elec_num_tab_local(1)
-    iorb =  occ(i,1)
-    hii += mo_one_e_integrals(iorb,iorb)
-    do j = i+1, elec_num_tab_local(1)
-      jorb = occ(j,1)
-      hii +=  mo_two_e_integrals_jj_anti(jorb,iorb)
-    enddo
-  enddo
-
-  ! beta - beta
-  do i = 1, elec_num_tab_local(2)
-    iorb =  occ(i,2)
-    hii += mo_one_e_integrals(iorb,iorb)
-    do j = i+1, elec_num_tab_local(2)
-      jorb = occ(j,2)
-      hii +=  mo_two_e_integrals_jj_anti(jorb,iorb)
-    enddo
-  enddo
-
-  ! alpha - beta
-  do i = 1, elec_num_tab_local(2)
-    iorb =  occ(i,2)
-    do j = 1, elec_num_tab_local(1)
-      jorb = occ(j,1)
-      hii +=  mo_two_e_integrals_jj(jorb,iorb)
-    enddo
-  enddo
-
-end