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18 KiB
18 KiB
Configuration Sigma Vector Helpers
Generate the singly excited configurations on-the-fly
The algorithm is based on the work by Garniron et. al. (see thesis Chap 5). The basic idea is to generate \(|\alpha\rangle\)'s on-the-fly.
The algorithm is based on the idea of splitting the list of \(|\alpha\rangle\)'s into blocks associated with a selected determinant \(|D_I\rangle\).
Create a function to return a list of alphas
Here we create a list of \(|\alpha\rangle\)'s associated with the input determinant \(|D_I\rangle\).
subroutine obtain_associated_alphaI(idxI, Icfg, alphasIcfg, NalphaIcfg, factor_alphaI)
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
real*8 ,intent(out) :: factor_alphaI(*)
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_8,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_8,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_8,i-1)))), POPCNT(IAND(Idomo,(IBSET(0_8,i-1))))
if(POPCNT(IAND(Isomo,(IBSET(0_8,i-1)))) .EQ. 0 .AND. POPCNT(IAND(Idomo,(IBSET(0_8,i-1)))) .EQ. 0) then
nvmos += 1
listvmos(nvmos) = i
vmotype(nvmos) = 1
else if(POPCNT(IAND(Isomo,(IBSET(0_8,i-1)))) .EQ. 1 .AND. POPCNT(IAND(Idomo,(IBSET(0_8,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)
!print *,"Nholes=",nholes," Nvmos=",nvmos, " idxi=",idxI
!do i = 1,nholes
! print *,i,"->",listholes(i)
!enddo
!do i = 1,nvmos
! print *,i,"->",listvmos(i)
!enddo
! TODO cfg_seniority_index
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(p .EQ. q) cycle
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),NalphaIcfg
!call debug_spindet(Idomo,1)
!call debug_spindet(Jdomo,1)
alphasIcfg(1,1,NalphaIcfg) = Jsomo
alphasIcfg(1,2,NalphaIcfg) = IOR(Jdomo,ISHFT(1_8,n_core_orb)-1)
endif
end do
end do
end subroutine
Given an \(\alpha\) CFG, return all the \(|I\rangle\) CFGs
Next step is to obtain the connected CFGs \(|I\rangle\) that belong to the selected space given a RI configuration \(|\alpha\rangle\).
subroutine obtain_connected_I_foralpha(idxI, Ialpha, connectedI, idxs_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 ,intent(in) :: idxI
integer(bit_kind),intent(in) :: Ialpha(N_int,2)
integer(bit_kind),intent(out) :: connectedI(N_int,2,*)
integer ,intent(out) :: idxs_connectedI(*)
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 :: IJsomo
integer*8 :: diffSOMO
integer*8 :: diffDOMO
integer :: ndiffSOMO
integer :: ndiffDOMO
integer :: i,j,k,l,p,q,nsomoJ,nsomoalpha,starti,endi,extyp,nholes
integer :: listholes(mo_num)
integer :: holetype(mo_num)
! find out all pq holes possible
nholes = 0
! holes in SOMO
Isomo = psi_configuration(1,1,idxI)
Idomo = psi_configuration(1,2,idxI)
do i = n_core_orb+1,n_core_orb + n_act_orb
if(POPCNT(IAND(Isomo,IBSET(0_8,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_8,i-1))) .EQ. 1) then
nholes += 1
listholes(nholes) = i
holetype(nholes) = 2
endif
end do
nconnectedI = 0
p = 0
q = 0
do i=idxI+1,N_configuration
Isomo = Ialpha(1,1)
Idomo = Ialpha(1,2)
Jsomo = psi_configuration(1,1,i)
Jdomo = psi_configuration(1,2,i)
!call debug_spindet(Isomo,1)
!call debug_spindet(Idomo,1)
!print *,"-J--i=",i,Idomo,Jdomo,">",N_configuration
!call debug_spindet(Jsomo,1)
!call debug_spindet(Jdomo,1)
diffSOMO = IEOR(Isomo,Jsomo)
diffDOMO = IEOR(Idomo,Jdomo)
ndiffSOMO = POPCNT(diffSOMO)
ndiffDOMO = POPCNT(diffDOMO)
if((ndiffSOMO + ndiffDOMO) .EQ. 0) cycle
!print *,"-I--i=",i,diffSOMO,diffDOMO!Isomo,Jsomo,ndiffSOMO,ndiffDOMO
!print *,POPCNT(IEOR(diffSOMO,diffDOMO)), ndiffDOMO
if(POPCNT(IEOR(diffSOMO,diffDOMO)) .LE. 1 .AND. ndiffDOMO .LT. 3) then
!call debug_spindet(Isomo,1)
!call debug_spindet(Idomo,1)
!print *,"-J--i=",i,Idomo,Jdomo,">",N_configuration
!call debug_spindet(Jsomo,1)
!call debug_spindet(Jdomo,1)
select case(ndiffDOMO)
case (0)
! SOMO -> VMO
!print *,"obt SOMO -> VMO"
extyp = 3
IJsomo = IEOR(Isomo, Jsomo)
p = TRAILZ(IAND(Isomo,IJsomo)) + 1
IJsomo = IBCLR(IJsomo,p-1)
q = TRAILZ(IJsomo) + 1
case (1)
! DOMO -> VMO
! or
! SOMO -> SOMO
nsomoJ = POPCNT(Jsomo)
nsomoalpha = POPCNT(Isomo)
if(nsomoJ .GT. nsomoalpha) then
! DOMO -> VMO
!print *,"obt DOMO -> VMO"
extyp = 2
p = TRAILZ(IEOR(Idomo,Jdomo)) + 1
Isomo = IEOR(Isomo, Jsomo)
Isomo = IBCLR(Isomo,p-1)
q = TRAILZ(Isomo) + 1
else
! SOMO -> SOMO
!print *,"obt SOMO -> SOMO"
extyp = 1
q = TRAILZ(IEOR(Idomo,Jdomo)) + 1
Isomo = IEOR(Isomo, Jsomo)
Isomo = IBCLR(Isomo,q-1)
p = TRAILZ(Isomo) + 1
end if
case (2)
! DOMO -> SOMO
!print *,"obt DOMO -> SOMO"
extyp = 4
IJsomo = IEOR(Isomo, Jsomo)
p = TRAILZ(IAND(Jsomo,IJsomo)) + 1
IJsomo = IBCLR(IJsomo,p-1)
q = TRAILZ(IJsomo) + 1
case default
print *,"something went wront in get connectedI"
end select
starti = psi_config_data(i,1)
endi = psi_config_data(i,2)
nconnectedI += 1
connectedI(:,:,nconnectedI) = psi_configuration(:,:,i)
idxs_connectedI(nconnectedI)=starti
excitationIds(1,nconnectedI)=p
excitationIds(2,nconnectedI)=q
excitationTypes(nconnectedI) = extyp
print *,"------ > output p,q in obt=",p,q
endif
end do
end subroutine obtain_connected_I_foralpha
print *,TRAILZ(8)
print *,IBCLR(8,TRAILZ(9))
print *,TRAILZ(IBCLR(8,TRAILZ(9)))
3 |
8 |
3 |
Function to get the NSOMOs (seniority)
function getNSOMO(Icfg) result(NSOMO)
implicit none
integer(bit_kind),intent(in) :: Icfg(N_int,2)
integer :: NSOMO
integer :: i
NSOMO = 0
do i = 1,N_int
NSOMO += POPCNT(Icfg(i,1))
enddo
end function getNSOMO
Function to convert p,q to model space ids
This function converts the real orbital ids \(i,j\) to model space ids \(p,q\) which depend only on the number of somos.
subroutine convertOrbIdsToModelSpaceIds(Ialpha, Jcfg, p, q, extype, pmodel, qmodel)
implicit none
BEGIN_DOC
! This function converts the orbital ids
! in real space to those used in model space
! in order to identify the matrices required
! for the calculation of MEs.
!
! The type of excitations are ordered as follows:
! Type 1 - SOMO -> SOMO
! Type 2 - DOMO -> VMO
! Type 3 - SOMO -> VMO
! Type 4 - DOMO -> SOMO
END_DOC
integer(bit_kind),intent(in) :: Ialpha(N_int,2)
integer(bit_kind),intent(in) :: Jcfg(N_int,2)
integer,intent(in) :: p,q
integer,intent(in) :: extype
integer,intent(out) :: pmodel,qmodel
integer*8 :: Isomo
integer*8 :: Idomo
integer*8 :: Jsomo
integer*8 :: Jdomo
integer*8 :: mask
integer*8 :: Isomotmp
integer*8 :: Jsomotmp
integer :: pos0,pos0prev
! TODO Flag (print) when model space indices is > 64
Isomo = Ialpha(1,1)
Idomo = Ialpha(1,2)
Jsomo = Jcfg(1,1)
Jdomo = Jcfg(1,2)
pos0prev = 0
pmodel = p
qmodel = q
if(p .EQ. q) then
pmodel = 1
qmodel = 1
else
!print *,"input pq=",p,q,"extype=",extype
!call debug_spindet(Isomo,1)
!call debug_spindet(Idomo,1)
!call debug_spindet(Jsomo,1)
!call debug_spindet(Jdomo,1)
select case(extype)
case (1)
! SOMO -> SOMO
! remove all domos
!print *,"type -> SOMO -> SOMO"
mask = ISHFT(1_8,p) - 1
Isomotmp = IAND(Isomo,mask)
pmodel = POPCNT(mask) - POPCNT(XOR(Isomotmp,mask))
mask = ISHFT(1_8,q) - 1
Isomotmp = IAND(Isomo,mask)
qmodel = POPCNT(mask) - POPCNT(XOR(Isomotmp,mask))
case (2)
! DOMO -> VMO
! remove all domos except one at p
!print *,"type -> DOMO -> VMO"
mask = ISHFT(1_8,p) - 1
Jsomotmp = IAND(Jsomo,mask)
pmodel = POPCNT(mask) - POPCNT(XOR(Jsomotmp,mask))
mask = ISHFT(1_8,q) - 1
Jsomotmp = IAND(Jsomo,mask)
qmodel = POPCNT(mask) - POPCNT(XOR(Jsomotmp,mask))
case (3)
! SOMO -> VMO
!print *,"type -> SOMO -> VMO"
!Isomo = IEOR(Isomo,Jsomo)
mask = ISHFT(1_8,p) - 1
Isomo = IAND(Isomo,mask)
pmodel = POPCNT(mask) - POPCNT(XOR(Isomo,mask))
mask = ISHFT(1_8,q) - 1
Jsomo = IAND(Jsomo,mask)
qmodel = POPCNT(mask) - POPCNT(XOR(Jsomo,mask))
case (4)
! DOMO -> SOMO
! remove all domos except one at p
!print *,"type -> DOMO -> SOMO"
!Isomo = IEOR(Isomo,Jsomo)
mask = ISHFT(1_8,p) - 1
Jsomo = IAND(Jsomo,mask)
pmodel = POPCNT(mask) - POPCNT(XOR(Jsomo,mask))
mask = ISHFT(1_8,q) - 1
Isomo = IAND(Isomo,mask)
qmodel = POPCNT(mask) - POPCNT(XOR(Isomo,mask))
case default
print *,"something is wrong in convertOrbIdsToModelSpaceIds"
end select
endif
!print *,p,q,"model ids=",pmodel,qmodel
end subroutine convertOrbIdsToModelSpaceIds
integer :: i
integer :: count
integer :: mask
integer :: isomo
count = 0
mask = ISHFT(1_8,5)-1
print *,mask
print *,POPCNT(mask)
isomo = 144
isomo = IAND(isomo,mask)
print *,isomo
print *,XOR(isomo,mask)
print *,POPCNT(mask) - POPCNT(XOR(isomo,mask))
31 |
5 |
16 |
15 |
1 |
print *,IBSET(0_8,4)-1
print *,POPCNT(IBSET(0_8,4)-1) - POPCNT(IAND(716,IBSET(0_8,4)-1))
print *,POPCNT(IBSET(0_8,8)-1) - POPCNT(IAND(716,IBSET(0_8,8)-1))
15 |
2 |
4 |