BEGIN_PROVIDER [double precision, SXvector_lowest, (nMonoEx)] implicit none integer :: i do i=2,nMonoEx+1 SXvector_lowest(i-1)=SXeigenvec(i,1) enddo END_PROVIDER BEGIN_PROVIDER [double precision, thresh_overlap_switch] implicit none thresh_overlap_switch = 0.5d0 END_PROVIDER BEGIN_PROVIDER [integer, max_overlap, (nMonoEx)] &BEGIN_PROVIDER [integer, n_max_overlap] &BEGIN_PROVIDER [integer, dim_n_max_overlap] implicit none double precision, allocatable :: vec_tmp(:) integer, allocatable :: iorder(:) allocate(vec_tmp(nMonoEx),iorder(nMonoEx)) integer :: i do i = 1, nMonoEx iorder(i) = i vec_tmp(i) = -dabs(SXvector_lowest(i)) enddo call dsort(vec_tmp,iorder,nMonoEx) n_max_overlap = 0 do i = 1, nMonoEx if(dabs(vec_tmp(i)).gt.thresh_overlap_switch)then n_max_overlap += 1 max_overlap(n_max_overlap) = iorder(i) endif enddo dim_n_max_overlap = max(1,n_max_overlap) END_PROVIDER BEGIN_PROVIDER [integer, orb_swap, (2,dim_n_max_overlap)] &BEGIN_PROVIDER [integer, index_orb_swap, (dim_n_max_overlap)] &BEGIN_PROVIDER [integer, n_orb_swap ] implicit none use bitmasks ! you need to include the bitmasks_module.f90 features integer :: i,imono,iorb,jorb,j n_orb_swap = 0 do i = 1, n_max_overlap imono = max_overlap(i) iorb = excit(1,imono) jorb = excit(2,imono) if (excit_class(imono) == "c-a" .and.hessmat2(imono,imono).gt.0.d0)then ! core --> active rotation n_orb_swap += 1 orb_swap(1,n_orb_swap) = iorb ! core orb_swap(2,n_orb_swap) = jorb ! active index_orb_swap(n_orb_swap) = imono else if (excit_class(imono) == "a-v" .and.hessmat2(imono,imono).gt.0.d0)then ! active --> virtual rotation n_orb_swap += 1 orb_swap(1,n_orb_swap) = jorb ! virtual orb_swap(2,n_orb_swap) = iorb ! active index_orb_swap(n_orb_swap) = imono endif enddo integer,allocatable :: orb_swap_tmp(:,:) allocate(orb_swap_tmp(2,dim_n_max_overlap)) do i = 1, n_orb_swap orb_swap_tmp(1,i) = orb_swap(1,i) orb_swap_tmp(2,i) = orb_swap(2,i) enddo integer(bit_kind), allocatable :: det_i(:),det_j(:) allocate(det_i(N_int),det_j(N_int)) logical, allocatable :: good_orb_rot(:) allocate(good_orb_rot(n_orb_swap)) integer, allocatable :: index_orb_swap_tmp(:) allocate(index_orb_swap_tmp(dim_n_max_overlap)) index_orb_swap_tmp = index_orb_swap good_orb_rot = .True. integer :: icount,k do i = 1, n_orb_swap if(.not.good_orb_rot(i))cycle det_i = 0_bit_kind call set_bit_to_integer(orb_swap(1,i),det_i,N_int) call set_bit_to_integer(orb_swap(2,i),det_i,N_int) do j = i+1, n_orb_swap det_j = 0_bit_kind call set_bit_to_integer(orb_swap(1,j),det_j,N_int) call set_bit_to_integer(orb_swap(2,j),det_j,N_int) icount = 0 do k = 1, N_int icount += popcnt(ior(det_i(k),det_j(k))) enddo if (icount.ne.4)then good_orb_rot(i) = .False. good_orb_rot(j) = .False. exit endif enddo enddo icount = n_orb_swap n_orb_swap = 0 do i = 1, icount if(good_orb_rot(i))then n_orb_swap += 1 index_orb_swap(n_orb_swap) = index_orb_swap_tmp(i) orb_swap(1,n_orb_swap) = orb_swap_tmp(1,i) orb_swap(2,n_orb_swap) = orb_swap_tmp(2,i) endif enddo if(n_orb_swap.gt.0)then print*,'n_orb_swap = ',n_orb_swap endif do i = 1, n_orb_swap print*,'imono = ',index_orb_swap(i) print*,orb_swap(1,i),'-->',orb_swap(2,i) enddo END_PROVIDER BEGIN_PROVIDER [double precision, switch_mo_coef, (ao_num,mo_num)] implicit none integer :: i,j,iorb,jorb switch_mo_coef = NatOrbsFCI do i = 1, n_orb_swap iorb = orb_swap(1,i) jorb = orb_swap(2,i) do j = 1, ao_num switch_mo_coef(j,jorb) = NatOrbsFCI(j,iorb) enddo do j = 1, ao_num switch_mo_coef(j,iorb) = NatOrbsFCI(j,jorb) enddo enddo END_PROVIDER