qp2/src/determinants/configuration_CI_sigma_helpers.irp.f

  subroutine obtain_associated_alphaI(idxI, Icfg, alphasIcfg, NalphaIcfg)
  implicit none
  use bitmasks
  BEGIN_DOC
  ! Documentation for alphasI
  ! Returns the associated alpha's for
  ! the input configuration Icfg.
  END_DOC

  integer,intent(in)                 :: idxI ! The id of the Ith CFG
  integer(bit_kind),intent(in)       :: Icfg(N_int,2)
  integer,intent(out)                :: NalphaIcfg
  integer(bit_kind),intent(out)      :: alphasIcfg(N_int,2,*)
  logical,dimension(:,:),allocatable :: tableUniqueAlphas
  integer                            :: listholes(mo_num)
  integer                            :: holetype(mo_num) ! 1-> SOMO 2->DOMO
  integer                            :: nholes
  integer                            :: nvmos
  integer                            :: listvmos(mo_num)
  integer                            :: vmotype(mo_num) ! 1 -> VMO 2 -> SOMO
  integer*8                          :: Idomo
  integer*8                          :: Isomo
  integer*8                          :: Jdomo
  integer*8                          :: Jsomo
  integer*8                          :: diffSOMO
  integer*8                          :: diffDOMO
  integer                            :: ndiffSOMO
  integer                            :: ndiffDOMO
  integer                            :: ndiffAll
  integer                            :: i
  integer                            :: j
  integer                            :: k
  integer                            :: hole
  integer                            :: p
  integer                            :: q
  integer                            :: countalphas
  logical                            :: pqAlreadyGenQ
  logical                            :: pqExistsQ
  Isomo = iand(reunion_of_act_virt_bitmask(1,1),Icfg(1,1))
  Idomo = iand(reunion_of_act_virt_bitmask(1,1),Icfg(1,2))
  !print*,"Input cfg"
  !call debug_spindet(Isomo,1)
  !call debug_spindet(Idomo,1)

  !print*,n_act_orb, "monum=",mo_num," n_core=",n_core_orb

  ! find out all pq holes possible
  nholes = 0
  ! holes in SOMO
  do i = n_core_orb+1,n_core_orb + n_act_orb
     if(POPCNT(IAND(Isomo,IBSET(0,i-1))) .EQ. 1) then
        nholes += 1
        listholes(nholes) = i
        holetype(nholes) = 1
     endif
  end do
  ! holes in DOMO
  do i = n_core_orb+1,n_core_orb + n_act_orb
     if(POPCNT(IAND(Idomo,IBSET(0,i-1))) .EQ. 1) then
        nholes += 1
        listholes(nholes) = i
        holetype(nholes) = 2
     endif
  end do

  ! find vmos
  listvmos = -1
  vmotype = -1
  nvmos = 0
  do i = n_core_orb+1,n_core_orb + n_act_orb
     !print *,i,IBSET(0,i-1),POPCNT(IAND(Isomo,(IBSET(0,i-1)))), POPCNT(IAND(Idomo,(IBSET(0,i-1))))
     if(POPCNT(IAND(Isomo,(IBSET(0,i-1)))) .EQ. 0 .AND. POPCNT(IAND(Idomo,(IBSET(0,i-1)))) .EQ. 0) then
        nvmos += 1
        listvmos(nvmos) = i
        vmotype(nvmos) = 1
     else if(POPCNT(IAND(Isomo,(IBSET(0,i-1)))) .EQ. 1 .AND. POPCNT(IAND(Idomo,(IBSET(0,i-1)))) .EQ. 0 ) then
        nvmos += 1
        listvmos(nvmos) = i
        vmotype(nvmos) = 2
     end if
  end do

  !print *,"Nvmo=",nvmos
  !print *,listvmos
  !print *,vmotype

  allocate(tableUniqueAlphas(mo_num,mo_num))
  tableUniqueAlphas = .FALSE.

  ! Now find the allowed (p,q) excitations
  Isomo = iand(reunion_of_act_virt_bitmask(1,1),Icfg(1,1))
  Idomo = iand(reunion_of_act_virt_bitmask(1,1),Icfg(1,2))
  !print *,"Isomo"
  !call debug_spindet(Isomo,1)
  !call debug_spindet(Idomo,1)
  do i = 1,nholes
     p = listholes(i)
     do j = 1,nvmos
        q = listvmos(j)
        if(p == q) cycle
        if(holetype(i) .EQ. 1 .AND. vmotype(j) .EQ. 1) then
           ! SOMO -> VMO
           Jsomo = IBCLR(Isomo,p-1)
           Jsomo = IBSET(Jsomo,q-1)
           Jdomo = Idomo
        else if(holetype(i) .EQ. 1 .AND. vmotype(j) .EQ. 2) then
           ! SOMO -> SOMO
           Jsomo = IBCLR(Isomo,p-1)
           Jsomo = IBCLR(Jsomo,q-1)
           Jdomo = IBSET(Idomo,q-1)
        else if(holetype(i) .EQ. 2 .AND. vmotype(j) .EQ. 1) then
           ! DOMO -> VMO
           Jsomo = IBSET(Isomo,p-1)
           Jsomo = IBSET(Jsomo,q-1)
           Jdomo = IBCLR(Idomo,p-1)
        else if(holetype(i) .EQ. 2 .AND. vmotype(j) .EQ. 2) then
           ! DOMO -> SOMO
           Jsomo = IBSET(Isomo,p-1)
           Jsomo = IBCLR(Jsomo,q-1)
           Jdomo = IBCLR(Idomo,p-1)
           Jdomo = IBSET(Jdomo,q-1)
        else
           print*,"Something went wrong in obtain_associated_alphaI"
        endif


        pqAlreadyGenQ = .FALSE.
        ! First check if it can be generated before
        do k = 1, idxI-1
           diffSOMO = IEOR(Jsomo,iand(reunion_of_act_virt_bitmask(1,1),psi_configuration(1,1,k)))
           diffDOMO = IEOR(Jdomo,iand(reunion_of_act_virt_bitmask(1,1),psi_configuration(1,2,k)))
           ndiffSOMO = POPCNT(diffSOMO)
           ndiffDOMO = POPCNT(diffDOMO)
           if(POPCNT(IEOR(diffSOMO,diffDOMO)) .LE. 1 .AND. ndiffDOMO .LT. 3) then
              pqAlreadyGenQ = .TRUE.
              !print *,i,k,ndiffSOMO,ndiffDOMO
              !call debug_spindet(Jsomo,1)
              !call debug_spindet(Jdomo,1)
              !call debug_spindet(iand(reunion_of_act_virt_bitmask(1,1),psi_configuration(1,1,k)),1)
              !call debug_spindet(iand(reunion_of_act_virt_bitmask(1,1),psi_configuration(1,2,k)),1)
              EXIT
           endif
        end do

        if(pqAlreadyGenQ) cycle

        pqExistsQ = .FALSE.
        ! now check if this exists in the selected list
        do k = idxI, N_configuration
           diffSOMO = IEOR(OR(reunion_of_act_virt_bitmask(1,1),Jsomo),psi_configuration(1,1,k))
           diffDOMO = IEOR(OR(reunion_of_act_virt_bitmask(1,1),Jdomo),psi_configuration(1,2,k))
           ndiffSOMO = POPCNT(diffSOMO)
           ndiffDOMO = POPCNT(diffDOMO)
           if((ndiffSOMO + ndiffDOMO) .EQ. 0) then
              pqExistsQ = .TRUE.
              EXIT
           endif
        end do

        if(.NOT. pqExistsQ) then
           tableUniqueAlphas(p,q) = .TRUE.
           !print *,p,q
           !call debug_spindet(Jsomo,1)
           !call debug_spindet(Jdomo,1)
        endif
     end do
  end do

  !print *,tableUniqueAlphas(:,:)

  ! prune list of alphas
  Isomo = Icfg(1,1)
  Idomo = Icfg(1,2)
  Jsomo = Icfg(1,1)
  Jdomo = Icfg(1,2)
  NalphaIcfg = 0
  do i = 1, nholes
     p = listholes(i)
     do j = 1, nvmos
        q = listvmos(j)
        if(tableUniqueAlphas(p,q)) then
           if(holetype(i) .EQ. 1 .AND. vmotype(j) .EQ. 1) then
              ! SOMO -> VMO
              Jsomo = IBCLR(Isomo,p-1)
              Jsomo = IBSET(Jsomo,q-1)
              Jdomo = Idomo
           else if(holetype(i) .EQ. 1 .AND. vmotype(j) .EQ. 2) then
              ! SOMO -> SOMO
              Jsomo = IBCLR(Isomo,p-1)
              Jsomo = IBCLR(Jsomo,q-1)
              Jdomo = IBSET(Idomo,q-1)
           else if(holetype(i) .EQ. 2 .AND. vmotype(j) .EQ. 1) then
              ! DOMO -> VMO
              Jsomo = IBSET(Isomo,p-1)
              Jsomo = IBSET(Jsomo,q-1)
              Jdomo = IBCLR(Idomo,p-1)
           else if(holetype(i) .EQ. 2 .AND. vmotype(j) .EQ. 2) then
              ! DOMO -> SOMO
              Jsomo = IBSET(Isomo,p-1)
              Jsomo = IBCLR(Jsomo,q-1)
              Jdomo = IBCLR(Idomo,p-1)
              Jdomo = IBSET(Jdomo,q-1)
           else
              print*,"Something went wrong in obtain_associated_alphaI"
           endif

           NalphaIcfg += 1
           !print *,p,q,"|",holetype(i),vmotype(j)
           !call debug_spindet(Jsomo,1)
           !call debug_spindet(Jdomo,1)
           alphasIcfg(1,1,NalphaIcfg) = Jsomo
           alphasIcfg(1,2,NalphaIcfg) = Jdomo
        endif
     end do
  end do

  end subroutine

subroutine obtain_connected_I_foralpha(Ialpha, connectedI, nconnectedI, excitationIds, excitationTypes)
  implicit none
  use bitmasks
  BEGIN_DOC
  ! Documentation for obtain_connected_I_foralpha
  ! This function returns all those selected configurations
  ! which are connected to the input configuration
  ! Ialpha by a single excitation.
  !
  ! The type of excitations are ordered as follows:
  ! Type 1 - SOMO -> SOMO
  ! Type 2 - DOMO -> VMO
  ! Type 3 - SOMO -> VMO
  ! Type 4 - DOMO -> SOMO
  !
  ! Order of operators
  ! \alpha> = a^\dag_p a_q |I> = E_pq |I>
  END_DOC
  integer(bit_kind),intent(in)             :: Ialpha(N_int,2)
  integer(bit_kind),intent(out)            :: connectedI(N_int,2,*)
  integer,intent(out)                      :: nconnectedI
  integer,intent(out)                      :: excitationIds(2,*)
  integer,intent(out)                      :: excitationTypes(*)
  integer*8                                :: Idomo
  integer*8                                :: Isomo
  integer*8                                :: Jdomo
  integer*8                                :: Jsomo
  integer*8                                :: diffSOMO
  integer*8                                :: diffDOMO
  integer                                  :: ndiffSOMO
  integer                                  :: ndiffDOMO
  integer :: i,j,k,l,p,q,nsomoI,nsomoalpha

  nconnectedI = 0

  Isomo = Ialpha(1,1)
  Idomo = Ialpha(1,2)
  do i=1,N_configuration
     diffSOMO = IEOR(Isomo,psi_configuration(1,1,i))
     diffDOMO = IEOR(Idomo,psi_configuration(1,2,i))
     ndiffSOMO = POPCNT(diffSOMO)
     ndiffDOMO = POPCNT(diffDOMO)
     if(POPCNT(IEOR(diffSOMO,diffDOMO)) .LE. 1 .AND. ndiffDOMO .LT. 3) then
        nconnectedI += 1
        connectedI(:,:,nconnectedI) = psi_configuration(:,:,i)
        select case(ndiffDOMO)
        case (0)
           ! SOMO -> VMO
           excitationTypes(nconnectedI) = 3
           Jsomo = IEOR(Isomo, psi_configuration(1,1,i))
           p = TRAILZ(iand(Jsomo,Isomo))
           q = TRAILZ(iand(Jsomo,psi_configuration(1,1,i)))
        case (1)
           ! DOMO -> VMO
           ! or
           ! SOMO -> SOMO
           nsomoI = POPCNT(psi_configuration(1,1,i))
           nsomoalpha = POPCNT(Isomo)
           if(nsomoI .GT. nsomoalpha) then
              ! DOMO -> VMO
              excitationTypes(nconnectedI) = 2
              Jdomo = IEOR(Idomo, psi_configuration(1,2,i))
              Jsomo = IEOR(Jdomo,IEOR(Isomo, psi_configuration(1,1,i)))
              p = TRAILZ(Jdomo)
              q = TRAILZ(Jsomo)
           else
              ! SOMO -> SOMO
              excitationTypes(nconnectedI) = 1
              Jdomo = IEOR(Idomo, psi_configuration(1,2,i))
              Jsomo = IEOR(Jdomo,IEOR(Isomo, psi_configuration(1,1,i)))
              q = TRAILZ(Jdomo)
              p = TRAILZ(Jsomo)
           end if
        case (2)
           ! DOMO -> SOMO
           excitationTypes(nconnectedI) = 4
           Jdomo = IEOR(Idomo, psi_configuration(1,2,i))
           p = TRAILZ(iand(Jdomo,Idomo))
           q = TRAILZ(iand(Jdomo,psi_configuration(1,2,i)))
        case default
           print *,"something went wront in get connectedI"
        end select
        excitationIds(1,nconnectedI)=p
        excitationIds(2,nconnectedI)=q
     endif
  end do


end subroutine obtain_connected_I_foralpha
Generator for mono \|\alpha> CFGs #143. 2021-02-01 14:54:11 +01:00			`subroutine obtain_associated_alphaI(idxI, Icfg, alphasIcfg, NalphaIcfg)`
			`implicit none`
			`use bitmasks`
			`BEGIN_DOC`
			`! Documentation for alphasI`
			`! Returns the associated alpha's for`
			`! the input configuration Icfg.`
			`END_DOC`

			`integer,intent(in) :: idxI ! The id of the Ith CFG`
			`integer(bit_kind),intent(in) :: Icfg(N_int,2)`
			`integer,intent(out) :: NalphaIcfg`
			`integer(bit_kind),intent(out) :: alphasIcfg(N_int,2,*)`
			`logical,dimension(:,:),allocatable :: tableUniqueAlphas`
			`integer :: listholes(mo_num)`
			`integer :: holetype(mo_num) ! 1-> SOMO 2->DOMO`
			`integer :: nholes`
			`integer :: nvmos`
			`integer :: listvmos(mo_num)`
			`integer :: vmotype(mo_num) ! 1 -> VMO 2 -> SOMO`
			`integer*8 :: Idomo`
			`integer*8 :: Isomo`
			`integer*8 :: Jdomo`
			`integer*8 :: Jsomo`
			`integer*8 :: diffSOMO`
			`integer*8 :: diffDOMO`
			`integer :: ndiffSOMO`
			`integer :: ndiffDOMO`
			`integer :: ndiffAll`
			`integer :: i`
			`integer :: j`
			`integer :: k`
			`integer :: hole`
			`integer :: p`
			`integer :: q`
			`integer :: countalphas`
			`logical :: pqAlreadyGenQ`
			`logical :: pqExistsQ`
			`Isomo = iand(reunion_of_act_virt_bitmask(1,1),Icfg(1,1))`
			`Idomo = iand(reunion_of_act_virt_bitmask(1,1),Icfg(1,2))`
			`!print*,"Input cfg"`
			`!call debug_spindet(Isomo,1)`
			`!call debug_spindet(Idomo,1)`

			`!print*,n_act_orb, "monum=",mo_num," n_core=",n_core_orb`

			`! find out all pq holes possible`
			`nholes = 0`
			`! holes in SOMO`
			`do i = n_core_orb+1,n_core_orb + n_act_orb`
types 2021-02-01 17:30:56 +01:00			`if(POPCNT(IAND(Isomo,IBSET(0,i-1))) .EQ. 1) then`
Generator for mono \|\alpha> CFGs #143. 2021-02-01 14:54:11 +01:00			`nholes += 1`
			`listholes(nholes) = i`
			`holetype(nholes) = 1`
			`endif`
			`end do`
			`! holes in DOMO`
			`do i = n_core_orb+1,n_core_orb + n_act_orb`
types 2021-02-01 17:30:56 +01:00			`if(POPCNT(IAND(Idomo,IBSET(0,i-1))) .EQ. 1) then`
Generator for mono \|\alpha> CFGs #143. 2021-02-01 14:54:11 +01:00			`nholes += 1`
			`listholes(nholes) = i`
			`holetype(nholes) = 2`
			`endif`
			`end do`

			`! find vmos`
			`listvmos = -1`
			`vmotype = -1`
			`nvmos = 0`
			`do i = n_core_orb+1,n_core_orb + n_act_orb`
			`!print *,i,IBSET(0,i-1),POPCNT(IAND(Isomo,(IBSET(0,i-1)))), POPCNT(IAND(Idomo,(IBSET(0,i-1))))`
types 2021-02-01 17:30:56 +01:00			`if(POPCNT(IAND(Isomo,(IBSET(0,i-1)))) .EQ. 0 .AND. POPCNT(IAND(Idomo,(IBSET(0,i-1)))) .EQ. 0) then`
Generator for mono \|\alpha> CFGs #143. 2021-02-01 14:54:11 +01:00			`nvmos += 1`
			`listvmos(nvmos) = i`
			`vmotype(nvmos) = 1`
types 2021-02-01 17:30:56 +01:00			`else if(POPCNT(IAND(Isomo,(IBSET(0,i-1)))) .EQ. 1 .AND. POPCNT(IAND(Idomo,(IBSET(0,i-1)))) .EQ. 0 ) then`
Generator for mono \|\alpha> CFGs #143. 2021-02-01 14:54:11 +01:00			`nvmos += 1`
			`listvmos(nvmos) = i`
			`vmotype(nvmos) = 2`
			`end if`
			`end do`

			`!print *,"Nvmo=",nvmos`
			`!print *,listvmos`
			`!print *,vmotype`

			`allocate(tableUniqueAlphas(mo_num,mo_num))`
			`tableUniqueAlphas = .FALSE.`

			`! Now find the allowed (p,q) excitations`
			`Isomo = iand(reunion_of_act_virt_bitmask(1,1),Icfg(1,1))`
			`Idomo = iand(reunion_of_act_virt_bitmask(1,1),Icfg(1,2))`
			`!print *,"Isomo"`
			`!call debug_spindet(Isomo,1)`
			`!call debug_spindet(Idomo,1)`
			`do i = 1,nholes`
			`p = listholes(i)`
			`do j = 1,nvmos`
			`q = listvmos(j)`
			`if(p == q) cycle`
			`if(holetype(i) .EQ. 1 .AND. vmotype(j) .EQ. 1) then`
			`! SOMO -> VMO`
			`Jsomo = IBCLR(Isomo,p-1)`
			`Jsomo = IBSET(Jsomo,q-1)`
			`Jdomo = Idomo`
			`else if(holetype(i) .EQ. 1 .AND. vmotype(j) .EQ. 2) then`
			`! SOMO -> SOMO`
			`Jsomo = IBCLR(Isomo,p-1)`
			`Jsomo = IBCLR(Jsomo,q-1)`
			`Jdomo = IBSET(Idomo,q-1)`
			`else if(holetype(i) .EQ. 2 .AND. vmotype(j) .EQ. 1) then`
			`! DOMO -> VMO`
			`Jsomo = IBSET(Isomo,p-1)`
			`Jsomo = IBSET(Jsomo,q-1)`
			`Jdomo = IBCLR(Idomo,p-1)`
			`else if(holetype(i) .EQ. 2 .AND. vmotype(j) .EQ. 2) then`
			`! DOMO -> SOMO`
			`Jsomo = IBSET(Isomo,p-1)`
			`Jsomo = IBCLR(Jsomo,q-1)`
			`Jdomo = IBCLR(Idomo,p-1)`
			`Jdomo = IBSET(Jdomo,q-1)`
			`else`
			`print*,"Something went wrong in obtain_associated_alphaI"`
			`endif`


			`pqAlreadyGenQ = .FALSE.`
			`! First check if it can be generated before`
			`do k = 1, idxI-1`
types 2021-02-01 17:30:56 +01:00			`diffSOMO = IEOR(Jsomo,iand(reunion_of_act_virt_bitmask(1,1),psi_configuration(1,1,k)))`
			`diffDOMO = IEOR(Jdomo,iand(reunion_of_act_virt_bitmask(1,1),psi_configuration(1,2,k)))`
Generator for mono \|\alpha> CFGs #143. 2021-02-01 14:54:11 +01:00			`ndiffSOMO = POPCNT(diffSOMO)`
			`ndiffDOMO = POPCNT(diffDOMO)`
types 2021-02-01 17:30:56 +01:00			`if(POPCNT(IEOR(diffSOMO,diffDOMO)) .LE. 1 .AND. ndiffDOMO .LT. 3) then`
Generator for mono \|\alpha> CFGs #143. 2021-02-01 14:54:11 +01:00			`pqAlreadyGenQ = .TRUE.`
			`!print *,i,k,ndiffSOMO,ndiffDOMO`
			`!call debug_spindet(Jsomo,1)`
			`!call debug_spindet(Jdomo,1)`
			`!call debug_spindet(iand(reunion_of_act_virt_bitmask(1,1),psi_configuration(1,1,k)),1)`
			`!call debug_spindet(iand(reunion_of_act_virt_bitmask(1,1),psi_configuration(1,2,k)),1)`
			`EXIT`
			`endif`
			`end do`

			`if(pqAlreadyGenQ) cycle`

			`pqExistsQ = .FALSE.`
			`! now check if this exists in the selected list`
			`do k = idxI, N_configuration`
types 2021-02-01 17:30:56 +01:00			`diffSOMO = IEOR(OR(reunion_of_act_virt_bitmask(1,1),Jsomo),psi_configuration(1,1,k))`
			`diffDOMO = IEOR(OR(reunion_of_act_virt_bitmask(1,1),Jdomo),psi_configuration(1,2,k))`
Generator for mono \|\alpha> CFGs #143. 2021-02-01 14:54:11 +01:00			`ndiffSOMO = POPCNT(diffSOMO)`
			`ndiffDOMO = POPCNT(diffDOMO)`
			`if((ndiffSOMO + ndiffDOMO) .EQ. 0) then`
			`pqExistsQ = .TRUE.`
			`EXIT`
			`endif`
			`end do`

			`if(.NOT. pqExistsQ) then`
			`tableUniqueAlphas(p,q) = .TRUE.`
			`!print *,p,q`
			`!call debug_spindet(Jsomo,1)`
			`!call debug_spindet(Jdomo,1)`
			`endif`
			`end do`
			`end do`

			`!print *,tableUniqueAlphas(:,:)`

			`! prune list of alphas`
			`Isomo = Icfg(1,1)`
			`Idomo = Icfg(1,2)`
			`Jsomo = Icfg(1,1)`
			`Jdomo = Icfg(1,2)`
			`NalphaIcfg = 0`
			`do i = 1, nholes`
			`p = listholes(i)`
			`do j = 1, nvmos`
			`q = listvmos(j)`
			`if(tableUniqueAlphas(p,q)) then`
			`if(holetype(i) .EQ. 1 .AND. vmotype(j) .EQ. 1) then`
			`! SOMO -> VMO`
			`Jsomo = IBCLR(Isomo,p-1)`
			`Jsomo = IBSET(Jsomo,q-1)`
			`Jdomo = Idomo`
			`else if(holetype(i) .EQ. 1 .AND. vmotype(j) .EQ. 2) then`
			`! SOMO -> SOMO`
			`Jsomo = IBCLR(Isomo,p-1)`
			`Jsomo = IBCLR(Jsomo,q-1)`
			`Jdomo = IBSET(Idomo,q-1)`
			`else if(holetype(i) .EQ. 2 .AND. vmotype(j) .EQ. 1) then`
			`! DOMO -> VMO`
			`Jsomo = IBSET(Isomo,p-1)`
			`Jsomo = IBSET(Jsomo,q-1)`
			`Jdomo = IBCLR(Idomo,p-1)`
			`else if(holetype(i) .EQ. 2 .AND. vmotype(j) .EQ. 2) then`
			`! DOMO -> SOMO`
			`Jsomo = IBSET(Isomo,p-1)`
			`Jsomo = IBCLR(Jsomo,q-1)`
			`Jdomo = IBCLR(Idomo,p-1)`
			`Jdomo = IBSET(Jdomo,q-1)`
			`else`
			`print*,"Something went wrong in obtain_associated_alphaI"`
			`endif`

			`NalphaIcfg += 1`
			`!print *,p,q,"\|",holetype(i),vmotype(j)`
			`!call debug_spindet(Jsomo,1)`
			`!call debug_spindet(Jdomo,1)`
			`alphasIcfg(1,1,NalphaIcfg) = Jsomo`
			`alphasIcfg(1,2,NalphaIcfg) = Jdomo`
			`endif`
			`end do`
			`end do`

			`end subroutine`
Added function for connected Is #143. 2021-02-01 16:52:40 +01:00
			`subroutine obtain_connected_I_foralpha(Ialpha, connectedI, nconnectedI, excitationIds, excitationTypes)`
			`implicit none`
			`use bitmasks`
			`BEGIN_DOC`
			`! Documentation for obtain_connected_I_foralpha`
			`! This function returns all those selected configurations`
			`! which are connected to the input configuration`
			`! Ialpha by a single excitation.`
			`!`
			`! The type of excitations are ordered as follows:`
			`! Type 1 - SOMO -> SOMO`
			`! Type 2 - DOMO -> VMO`
			`! Type 3 - SOMO -> VMO`
			`! Type 4 - DOMO -> SOMO`
			`!`
			`! Order of operators`
			`! \alpha> = a^\dag_p a_q \|I> = E_pq \|I>`
			`END_DOC`
			`integer(bit_kind),intent(in) :: Ialpha(N_int,2)`
			`integer(bit_kind),intent(out) :: connectedI(N_int,2,*)`
			`integer,intent(out) :: nconnectedI`
			`integer,intent(out) :: excitationIds(2,*)`
			`integer,intent(out) :: excitationTypes(*)`
			`integer*8 :: Idomo`
			`integer*8 :: Isomo`
			`integer*8 :: Jdomo`
			`integer*8 :: Jsomo`
			`integer*8 :: diffSOMO`
			`integer*8 :: diffDOMO`
			`integer :: ndiffSOMO`
			`integer :: ndiffDOMO`
			`integer :: i,j,k,l,p,q,nsomoI,nsomoalpha`

			`nconnectedI = 0`

			`Isomo = Ialpha(1,1)`
			`Idomo = Ialpha(1,2)`
			`do i=1,N_configuration`
types 2021-02-01 17:30:56 +01:00			`diffSOMO = IEOR(Isomo,psi_configuration(1,1,i))`
			`diffDOMO = IEOR(Idomo,psi_configuration(1,2,i))`
Added function for connected Is #143. 2021-02-01 16:52:40 +01:00			`ndiffSOMO = POPCNT(diffSOMO)`
			`ndiffDOMO = POPCNT(diffDOMO)`
types 2021-02-01 17:30:56 +01:00			`if(POPCNT(IEOR(diffSOMO,diffDOMO)) .LE. 1 .AND. ndiffDOMO .LT. 3) then`
Added function for connected Is #143. 2021-02-01 16:52:40 +01:00			`nconnectedI += 1`
			`connectedI(:,:,nconnectedI) = psi_configuration(:,:,i)`
			`select case(ndiffDOMO)`
			`case (0)`
			`! SOMO -> VMO`
			`excitationTypes(nconnectedI) = 3`
types 2021-02-01 17:30:56 +01:00			`Jsomo = IEOR(Isomo, psi_configuration(1,1,i))`
Added function for connected Is #143. 2021-02-01 16:52:40 +01:00			`p = TRAILZ(iand(Jsomo,Isomo))`
			`q = TRAILZ(iand(Jsomo,psi_configuration(1,1,i)))`
			`case (1)`
			`! DOMO -> VMO`
			`! or`
			`! SOMO -> SOMO`
			`nsomoI = POPCNT(psi_configuration(1,1,i))`
			`nsomoalpha = POPCNT(Isomo)`
			`if(nsomoI .GT. nsomoalpha) then`
			`! DOMO -> VMO`
			`excitationTypes(nconnectedI) = 2`
types 2021-02-01 17:30:56 +01:00			`Jdomo = IEOR(Idomo, psi_configuration(1,2,i))`
			`Jsomo = IEOR(Jdomo,IEOR(Isomo, psi_configuration(1,1,i)))`
Added function for connected Is #143. 2021-02-01 16:52:40 +01:00			`p = TRAILZ(Jdomo)`
			`q = TRAILZ(Jsomo)`
			`else`
			`! SOMO -> SOMO`
			`excitationTypes(nconnectedI) = 1`
types 2021-02-01 17:30:56 +01:00			`Jdomo = IEOR(Idomo, psi_configuration(1,2,i))`
			`Jsomo = IEOR(Jdomo,IEOR(Isomo, psi_configuration(1,1,i)))`
Added function for connected Is #143. 2021-02-01 16:52:40 +01:00			`q = TRAILZ(Jdomo)`
			`p = TRAILZ(Jsomo)`
			`end if`
			`case (2)`
			`! DOMO -> SOMO`
			`excitationTypes(nconnectedI) = 4`
types 2021-02-01 17:30:56 +01:00			`Jdomo = IEOR(Idomo, psi_configuration(1,2,i))`
Added function for connected Is #143. 2021-02-01 16:52:40 +01:00			`p = TRAILZ(iand(Jdomo,Idomo))`
			`q = TRAILZ(iand(Jdomo,psi_configuration(1,2,i)))`
			`case default`
			`print *,"something went wront in get connectedI"`
			`end select`
			`excitationIds(1,nconnectedI)=p`
			`excitationIds(2,nconnectedI)=q`
			`endif`
			`end do`


			`end subroutine obtain_connected_I_foralpha`