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QuantumPackage/src/tc_bi_ortho/slater_tc_slow.irp.f

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! ---
subroutine htilde_mu_mat_bi_ortho_tot_slow(key_j, key_i, Nint, htot)
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BEGIN_DOC
! <key_j | H_tilde | key_i> where |key_j> is developed on the LEFT basis and |key_i> is developed on the RIGHT basis
!!
!! WARNING !!
!
! Non hermitian !!
END_DOC
use bitmasks
implicit none
integer, intent(in) :: Nint
integer(bit_kind), intent(in) :: key_j(Nint,2),key_i(Nint,2)
double precision, intent(out) :: htot
double precision :: hmono, htwoe, hthree
integer :: degree
call get_excitation_degree(key_j, key_i, degree, Nint)
if(degree.gt.2)then
htot = 0.d0
else
call htilde_mu_mat_bi_ortho_slow(key_j, key_i, Nint, hmono, htwoe, hthree, htot)
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endif
end subroutine htilde_mu_mat_bi_ortho_tot_slow
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! --
subroutine htilde_mu_mat_bi_ortho_slow(key_j, key_i, Nint, hmono, htwoe, hthree, htot)
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BEGIN_DOC
!
! <key_j | H_tilde | key_i> where |key_j> is developed on the LEFT basis and |key_i> is developed on the RIGHT basis
!!
! Returns the detail of the matrix element in terms of single, two and three electron contribution.
!! WARNING !!
!
! Non hermitian !!
!
END_DOC
use bitmasks
implicit none
integer, intent(in) :: Nint
integer(bit_kind), intent(in) :: key_i(Nint,2), key_j(Nint,2)
double precision, intent(out) :: hmono, htwoe, hthree, htot
integer :: degree
hmono = 0.d0
htwoe = 0.d0
htot = 0.d0
hthree = 0.D0
call get_excitation_degree(key_i, key_j, degree, Nint)
if(degree.gt.2) return
if(degree == 0)then
call diag_htilde_mu_mat_bi_ortho_slow(Nint, key_i, hmono, htwoe, htot)
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else if (degree == 1)then
call single_htilde_mu_mat_bi_ortho_slow(Nint, key_j, key_i, hmono, htwoe, htot)
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else if(degree == 2)then
call double_htilde_mu_mat_bi_ortho_slow(Nint, key_j, key_i, hmono, htwoe, htot)
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endif
if(three_body_h_tc) then
if(degree == 2) then
if(.not.double_normal_ord.and.elec_num.gt.2.and.three_e_5_idx_term) then
call double_htilde_three_body_ints_bi_ort_slow(Nint, key_j, key_i, hthree)
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endif
else if(degree == 1.and.elec_num.gt.2.and.three_e_4_idx_term) then
call single_htilde_three_body_ints_bi_ort_slow(Nint, key_j, key_i, hthree)
else if(degree == 0.and.elec_num.gt.2.and.three_e_3_idx_term) then
call diag_htilde_three_body_ints_bi_ort_slow(Nint, key_i, hthree)
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endif
endif
htot = hmono + htwoe + hthree
if(degree==0) then
htot += nuclear_repulsion
endif
end
! ---
subroutine diag_htilde_mu_mat_bi_ortho_slow(Nint, key_i, hmono, htwoe, htot)
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BEGIN_DOC
! diagonal element of htilde ONLY FOR ONE- AND TWO-BODY TERMS
END_DOC
use bitmasks
implicit none
integer, intent(in) :: Nint
integer(bit_kind), intent(in) :: key_i(Nint,2)
double precision, intent(out) :: hmono,htwoe,htot
integer :: occ(Nint*bit_kind_size,2)
integer :: Ne(2), i, j, ii, jj, ispin, jspin, k, kk
double precision :: get_mo_two_e_integral_tc_int
integer(bit_kind) :: key_i_core(Nint,2)
! PROVIDE mo_two_e_integrals_tc_int_in_map mo_bi_ortho_tc_two_e
!
! PROVIDE mo_integrals_erf_map core_energy nuclear_repulsion core_bitmask
! PROVIDE core_fock_operator
!
! PROVIDE j1b_gauss
! if(core_tc_op)then
! print*,'core_tc_op not already taken into account for bi ortho'
! print*,'stopping ...'
! stop
! do i = 1, Nint
! key_i_core(i,1) = xor(key_i(i,1),core_bitmask(i,1))
! key_i_core(i,2) = xor(key_i(i,2),core_bitmask(i,2))
! enddo
! call bitstring_to_list_ab(key_i_core, occ, Ne, Nint)
! hmono = core_energy - nuclear_repulsion
! else
call bitstring_to_list_ab(key_i, occ, Ne, Nint)
hmono = 0.d0
! endif
htwoe= 0.d0
htot = 0.d0
do ispin = 1, 2
do i = 1, Ne(ispin) !
ii = occ(i,ispin)
hmono += mo_bi_ortho_tc_one_e(ii,ii)
! if(j1b_gauss .eq. 1) then
! print*,'j1b not implemented for bi ortho TC'
! print*,'stopping ....'
! stop
! !hmono += mo_j1b_gauss_hermI (ii,ii) &
! ! + mo_j1b_gauss_hermII (ii,ii) &
! ! + mo_j1b_gauss_nonherm(ii,ii)
! endif
! if(core_tc_op)then
! print*,'core_tc_op not already taken into account for bi ortho'
! print*,'stopping ...'
! stop
! hmono += core_fock_operator(ii,ii) ! add the usual Coulomb - Exchange from the core
! endif
enddo
enddo
! alpha/beta two-body
ispin = 1
jspin = 2
do i = 1, Ne(ispin) ! electron 1 (so it can be associated to mu(r1))
ii = occ(i,ispin)
do j = 1, Ne(jspin) ! electron 2
jj = occ(j,jspin)
htwoe += mo_bi_ortho_tc_two_e(jj,ii,jj,ii)
enddo
enddo
! alpha/alpha two-body
do i = 1, Ne(ispin)
ii = occ(i,ispin)
do j = i+1, Ne(ispin)
jj = occ(j,ispin)
htwoe += mo_bi_ortho_tc_two_e(ii,jj,ii,jj) - mo_bi_ortho_tc_two_e(ii,jj,jj,ii)
enddo
enddo
! beta/beta two-body
do i = 1, Ne(jspin)
ii = occ(i,jspin)
do j = i+1, Ne(jspin)
jj = occ(j,jspin)
htwoe += mo_bi_ortho_tc_two_e(ii,jj,ii,jj) - mo_bi_ortho_tc_two_e(ii,jj,jj,ii)
enddo
enddo
htot = hmono + htwoe
end
subroutine double_htilde_mu_mat_bi_ortho_slow(Nint, key_j, key_i, hmono, htwoe, htot)
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BEGIN_DOC
! <key_j | H_tilde | key_i> for double excitation ONLY FOR ONE- AND TWO-BODY TERMS
!!
!! WARNING !!
!
! Non hermitian !!
END_DOC
use bitmasks
implicit none
integer, intent(in) :: Nint
integer(bit_kind), intent(in) :: key_j(Nint,2), key_i(Nint,2)
double precision, intent(out) :: hmono, htwoe, htot
integer :: occ(Nint*bit_kind_size,2)
integer :: Ne(2), i, j, ii, jj, ispin, jspin, k, kk
integer :: degree,exc(0:2,2,2)
integer :: h1, p1, h2, p2, s1, s2
integer :: other_spin(2)
integer(bit_kind) :: key_i_core(Nint,2)
double precision :: get_mo_two_e_integral_tc_int,phase
! PROVIDE mo_two_e_integrals_tc_int_in_map mo_bi_ortho_tc_two_e
other_spin(1) = 2
other_spin(2) = 1
call get_excitation_degree(key_i, key_j, degree, Nint)
hmono = 0.d0
htwoe= 0.d0
htot = 0.d0
if(degree.ne.2)then
return
endif
call bitstring_to_list_ab(key_i, occ, Ne, Nint)
call get_double_excitation(key_i, key_j, exc, phase, Nint)
call decode_exc(exc, 2, h1, p1, h2, p2, s1, s2)
if(s1.ne.s2)then
! opposite spin two-body
! key_j, key_i
htwoe = mo_bi_ortho_tc_two_e(p2,p1,h2,h1)
if(three_body_h_tc.and.double_normal_ord.and.+Ne(1).gt.2)then
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htwoe += normal_two_body_bi_orth(p2,h2,p1,h1)!!! WTF ???
endif
else
! same spin two-body
! direct terms
htwoe = mo_bi_ortho_tc_two_e(p2,p1,h2,h1)
! exchange terms
htwoe -= mo_bi_ortho_tc_two_e(p1,p2,h2,h1)
if(three_body_h_tc.and.double_normal_ord.and.+Ne(1).gt.2)then
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htwoe -= normal_two_body_bi_orth(h2,p1,h1,p2)!!! WTF ???
htwoe += normal_two_body_bi_orth(h1,p1,h2,p2)!!! WTF ???
endif
endif
htwoe *= phase
htot = htwoe
end
subroutine single_htilde_mu_mat_bi_ortho_slow(Nint, key_j, key_i, hmono, htwoe, htot)
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BEGIN_DOC
! <key_j | H_tilde | key_i> for single excitation ONLY FOR ONE- AND TWO-BODY TERMS
!!
!! WARNING !!
!
! Non hermitian !!
END_DOC
use bitmasks
implicit none
integer, intent(in) :: Nint
integer(bit_kind), intent(in) :: key_j(Nint,2), key_i(Nint,2)
double precision, intent(out) :: hmono, htwoe, htot
integer :: occ(Nint*bit_kind_size,2)
integer :: Ne(2), i, j, ii, jj, ispin, jspin, k, kk
integer :: degree,exc(0:2,2,2)
integer :: h1, p1, h2, p2, s1, s2
double precision :: get_mo_two_e_integral_tc_int, phase
double precision :: direct_int, exchange_int_12, exchange_int_23, exchange_int_13
integer :: other_spin(2)
integer(bit_kind) :: key_j_core(Nint,2), key_i_core(Nint,2)
! PROVIDE mo_two_e_integrals_tc_int_in_map mo_bi_ortho_tc_two_e
!
! PROVIDE core_bitmask core_fock_operator mo_integrals_erf_map
! PROVIDE j1b_gauss
other_spin(1) = 2
other_spin(2) = 1
hmono = 0.d0
htwoe= 0.d0
htot = 0.d0
call get_excitation_degree(key_i, key_j, degree, Nint)
if(degree.ne.1)then
return
endif
! if(core_tc_op)then
! print*,'core_tc_op not already taken into account for bi ortho'
! print*,'stopping ...'
! stop
! do i = 1, Nint
! key_i_core(i,1) = xor(key_i(i,1),core_bitmask(i,1))
! key_i_core(i,2) = xor(key_i(i,2),core_bitmask(i,2))
! key_j_core(i,1) = xor(key_j(i,1),core_bitmask(i,1))
! key_j_core(i,2) = xor(key_j(i,2),core_bitmask(i,2))
! enddo
! call bitstring_to_list_ab(key_i_core, occ, Ne, Nint)
! else
call bitstring_to_list_ab(key_i, occ, Ne, Nint)
! endif
call get_single_excitation(key_i, key_j, exc, phase, Nint)
call decode_exc(exc,1,h1,p1,h2,p2,s1,s2)
! if(h1==14.and.p1==2)then
! print*,'h1,p1 old = ',h1,p1
! endif
hmono = mo_bi_ortho_tc_one_e(p1,h1) * phase
! if(j1b_gauss .eq. 1) then
! print*,'j1b not implemented for bi ortho TC'
! print*,'stopping ....'
! stop
! !hmono += ( mo_j1b_gauss_hermI (h1,p1) &
! ! + mo_j1b_gauss_hermII (h1,p1) &
! ! + mo_j1b_gauss_nonherm(h1,p1) ) * phase
! endif
! if(core_tc_op)then
! print*,'core_tc_op not already taken into account for bi ortho'
! print*,'stopping ...'
! stop
! hmono += phase * core_fock_operator(h1,p1)
! endif
! alpha/beta two-body
ispin = other_spin(s1)
if(s1==1)then
! single alpha
do i = 1, Ne(ispin) ! electron 2
ii = occ(i,ispin)
htwoe += mo_bi_ortho_tc_two_e(ii,p1,ii,h1)
enddo
else
! single beta
do i = 1, Ne(ispin) ! electron 1
ii = occ(i,ispin)
htwoe += mo_bi_ortho_tc_two_e(p1,ii,h1,ii)
enddo
endif
! ! same spin two-body
do i = 1, Ne(s1)
ii = occ(i,s1)
! (h1p1|ii ii) - (h1 ii| p1 ii)
htwoe += mo_bi_ortho_tc_two_e(ii,p1,ii,h1) - mo_bi_ortho_tc_two_e(p1,ii,ii,h1)
enddo
htwoe *= phase
htot = hmono + htwoe
end