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quantum_package/plugins/Properties/slater_rules_mono_electronic.irp.f
Thomas Applencourt 6a91e63cf3 Move into plugins
2015-06-17 18:23:56 +02:00

340 lines
9.8 KiB
Fortran

subroutine i_O1_j(array,key_i,key_j,Nint,hij)
use bitmasks
implicit none
BEGIN_DOC
! Returns <i|O1|j> where i and j are determinants
! and O1 is a ONE BODY OPERATOR
! array is the array of the mono electronic operator
! on the MO basis
END_DOC
integer, intent(in) :: Nint
integer(bit_kind), intent(in) :: key_i(Nint,2), key_j(Nint,2)
double precision, intent(out) :: hij
double precision, intent(in) :: array(mo_tot_num_align,mo_tot_num)
integer :: exc(0:2,2,2)
integer :: degree
integer :: m,p
double precision :: diag_O1_mat_elem, phase
ASSERT (Nint > 0)
ASSERT (Nint == N_int)
ASSERT (sum(popcnt(key_i(:,1))) == elec_alpha_num)
ASSERT (sum(popcnt(key_i(:,2))) == elec_beta_num)
ASSERT (sum(popcnt(key_j(:,1))) == elec_alpha_num)
ASSERT (sum(popcnt(key_j(:,2))) == elec_beta_num)
hij = 0.d0
!DEC$ FORCEINLINE
call get_excitation_degree(key_i,key_j,degree,Nint)
select case (degree)
case (2)
hij = 0.d0
case (1)
call get_mono_excitation(key_i,key_j,exc,phase,Nint)
if (exc(0,1,1) == 1) then
! Mono alpha
m = exc(1,1,1)
p = exc(1,2,1)
else
! Mono beta
m = exc(1,1,2)
p = exc(1,2,2)
endif
hij = phase* array(m,p)
case (0)
hij = diag_O1_mat_elem(array,key_i,Nint)
end select
end
subroutine i_O1_psi(array,key,keys,coef,Nint,Ndet,Ndet_max,Nstate,i_H_psi_array)
use bitmasks
implicit none
integer, intent(in) :: Nint, Ndet,Ndet_max,Nstate
double precision, intent(in) :: array(mo_tot_num_align,mo_tot_num)
integer(bit_kind), intent(in) :: keys(Nint,2,Ndet)
integer(bit_kind), intent(in) :: key(Nint,2)
double precision, intent(in) :: coef(Ndet_max,Nstate)
double precision, intent(out) :: i_H_psi_array(Nstate)
integer :: i, ii,j
double precision :: phase
integer :: exc(0:2,2,2)
double precision :: hij
integer :: idx(0:Ndet)
BEGIN_DOC
! <key|O1|psi> for the various Nstates
! and O1 is a ONE BODY OPERATOR
! array is the array of the mono electronic operator
! on the MO basis
END_DOC
ASSERT (Nint > 0)
ASSERT (N_int == Nint)
ASSERT (Nstate > 0)
ASSERT (Ndet > 0)
ASSERT (Ndet_max >= Ndet)
i_H_psi_array = 0.d0
call filter_connected_mono(keys,key,Nint,Ndet,idx)
do ii=1,idx(0)
i = idx(ii)
!DEC$ FORCEINLINE
call i_O1_j(array,keys(1,1,i),key,Nint,hij)
do j = 1, Nstate
i_H_psi_array(j) = i_H_psi_array(j) + coef(i,j)*hij
enddo
enddo
end
double precision function diag_O1_mat_elem(array,det_in,Nint)
use bitmasks
implicit none
BEGIN_DOC
! Computes <i|O1|i>
END_DOC
integer,intent(in) :: Nint
integer(bit_kind),intent(in) :: det_in(Nint,2)
double precision, intent(in) :: array(mo_tot_num_align,mo_tot_num)
integer :: i, ispin,tmp
integer :: occ_det(Nint*bit_kind_size,2)
ASSERT (Nint > 0)
ASSERT (sum(popcnt(det_in(:,1))) == elec_alpha_num)
ASSERT (sum(popcnt(det_in(:,2))) == elec_beta_num)
call bitstring_to_list(det_in(1,1), occ_det(1,1), tmp, Nint)
call bitstring_to_list(det_in(1,2), occ_det(1,2), tmp, Nint)
diag_O1_mat_elem = 0.d0
do ispin = 1, 2
do i = 1, elec_num_tab(ispin)
diag_O1_mat_elem += array(occ_det(i,ispin),occ_det(i,ispin))
enddo
enddo
end
subroutine i_O1_psi_alpha_beta(array,key,keys,coef,Nint,Ndet,Ndet_max,Nstate,i_H_psi_array)
use bitmasks
implicit none
integer, intent(in) :: Nint, Ndet,Ndet_max,Nstate
double precision, intent(in) :: array(mo_tot_num_align,mo_tot_num)
integer(bit_kind), intent(in) :: keys(Nint,2,Ndet)
integer(bit_kind), intent(in) :: key(Nint,2)
double precision, intent(in) :: coef(Ndet_max,Nstate)
double precision, intent(out) :: i_H_psi_array(Nstate)
integer :: i, ii,j
double precision :: phase
integer :: exc(0:2,2,2)
double precision :: hij
integer :: idx(0:Ndet)
BEGIN_DOC
! <key|O1(alpha) - O1(beta)|psi> for the various Nstates
! and O1 is a ONE BODY OPERATOR
! array is the array of the mono electronic operator
! on the MO basis
END_DOC
ASSERT (Nint > 0)
ASSERT (N_int == Nint)
ASSERT (Nstate > 0)
ASSERT (Ndet > 0)
ASSERT (Ndet_max >= Ndet)
i_H_psi_array = 0.d0
call filter_connected_mono(keys,key,Nint,Ndet,idx)
do ii=1,idx(0)
i = idx(ii)
!DEC$ FORCEINLINE
call i_O1_j_alpha_beta(array,keys(1,1,i),key,Nint,hij)
do j = 1, Nstate
i_H_psi_array(j) = i_H_psi_array(j) + coef(i,j)*hij
enddo
enddo
end
subroutine i_O1_j_alpha_beta(array,key_i,key_j,Nint,hij)
use bitmasks
implicit none
BEGIN_DOC
! Returns <i|O1(alpha) - O1(beta)|j> where i and j are determinants
! and O1 is a ONE BODY OPERATOR
! array is the array of the mono electronic operator
! on the MO basis
END_DOC
integer, intent(in) :: Nint
integer(bit_kind), intent(in) :: key_i(Nint,2), key_j(Nint,2)
double precision, intent(out) :: hij
double precision, intent(in) :: array(mo_tot_num_align,mo_tot_num)
integer :: exc(0:2,2,2)
integer :: degree
integer :: m,p
double precision :: diag_O1_mat_elem_alpha_beta, phase
ASSERT (Nint > 0)
ASSERT (Nint == N_int)
ASSERT (sum(popcnt(key_i(:,1))) == elec_alpha_num)
ASSERT (sum(popcnt(key_i(:,2))) == elec_beta_num)
ASSERT (sum(popcnt(key_j(:,1))) == elec_alpha_num)
ASSERT (sum(popcnt(key_j(:,2))) == elec_beta_num)
hij = 0.d0
!DEC$ FORCEINLINE
call get_excitation_degree(key_i,key_j,degree,Nint)
select case (degree)
case (2)
hij = 0.d0
case (1)
call get_mono_excitation(key_i,key_j,exc,phase,Nint)
if (exc(0,1,1) == 1) then
! Mono alpha
m = exc(1,1,1)
p = exc(1,2,1)
hij = phase* array(m,p)
else
! Mono beta
m = exc(1,1,2)
p = exc(1,2,2)
hij = -phase* array(m,p)
endif
case (0)
hij = diag_O1_mat_elem_alpha_beta(array,key_i,Nint)
end select
end
double precision function diag_O1_mat_elem_alpha_beta(array,det_in,Nint)
use bitmasks
implicit none
BEGIN_DOC
! Computes <i|O1(alpha) -O1(beta)|i>
END_DOC
integer,intent(in) :: Nint
integer(bit_kind),intent(in) :: det_in(Nint,2)
double precision, intent(in) :: array(mo_tot_num_align,mo_tot_num)
integer :: i, ispin,tmp
integer :: occ_det(Nint*bit_kind_size,2)
ASSERT (Nint > 0)
ASSERT (sum(popcnt(det_in(:,1))) == elec_alpha_num)
ASSERT (sum(popcnt(det_in(:,2))) == elec_beta_num)
call bitstring_to_list(det_in(1,1), occ_det(1,1), tmp, Nint)
call bitstring_to_list(det_in(1,2), occ_det(1,2), tmp, Nint)
diag_O1_mat_elem_alpha_beta = 0.d0
ispin = 1
do i = 1, elec_num_tab(ispin)
diag_O1_mat_elem_alpha_beta += array(occ_det(i,ispin),occ_det(i,ispin))
enddo
ispin = 2
do i = 1, elec_num_tab(ispin)
diag_O1_mat_elem_alpha_beta -= array(occ_det(i,ispin),occ_det(i,ispin))
enddo
end
subroutine filter_connected_mono(key1,key2,Nint,sze,idx)
use bitmasks
implicit none
BEGIN_DOC
! Filters out the determinants that are not connected through PURE
!
! MONO EXCITATIONS OPERATORS (a^{\dagger}j a_i)
!
! returns the array idx which contains the index of the
!
! determinants in the array key1 that interact
!
! via some PURE MONO EXCITATIONS OPERATORS
!
! idx(0) is the number of determinants that interact with key1
END_DOC
integer, intent(in) :: Nint, sze
integer(bit_kind), intent(in) :: key1(Nint,2,sze)
integer(bit_kind), intent(in) :: key2(Nint,2)
integer, intent(out) :: idx(0:sze)
integer :: i,j,l
integer :: degree_x2
ASSERT (Nint > 0)
ASSERT (sze >= 0)
l=1
if (Nint==1) then
!DIR$ LOOP COUNT (1000)
do i=1,sze
degree_x2 = popcnt( xor( key1(1,1,i), key2(1,1))) &
+ popcnt( xor( key1(1,2,i), key2(1,2)))
if (degree_x2 > 3) then
cycle
else
idx(l) = i
l = l+1
endif
enddo
else if (Nint==2) then
!DIR$ LOOP COUNT (1000)
do i=1,sze
degree_x2 = popcnt(xor( key1(1,1,i), key2(1,1))) + &
popcnt(xor( key1(2,1,i), key2(2,1))) + &
popcnt(xor( key1(1,2,i), key2(1,2))) + &
popcnt(xor( key1(2,2,i), key2(2,2)))
if (degree_x2 > 3) then
cycle
else
idx(l) = i
l = l+1
endif
enddo
else if (Nint==3) then
!DIR$ LOOP COUNT (1000)
do i=1,sze
degree_x2 = popcnt(xor( key1(1,1,i), key2(1,1))) + &
popcnt(xor( key1(1,2,i), key2(1,2))) + &
popcnt(xor( key1(2,1,i), key2(2,1))) + &
popcnt(xor( key1(2,2,i), key2(2,2))) + &
popcnt(xor( key1(3,1,i), key2(3,1))) + &
popcnt(xor( key1(3,2,i), key2(3,2)))
if (degree_x2 > 3) then
cycle
else
idx(l) = i
l = l+1
endif
enddo
else
!DIR$ LOOP COUNT (1000)
do i=1,sze
degree_x2 = 0
!DEC$ LOOP COUNT MIN(4)
do j=1,Nint
degree_x2 = degree_x2+ popcnt(xor( key1(j,1,i), key2(j,1))) +&
popcnt(xor( key1(j,2,i), key2(j,2)))
if (degree_x2 > 3) then
exit
endif
enddo
if (degree_x2 <= 3) then
idx(l) = i
l = l+1
endif
enddo
endif
idx(0) = l-1
end