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186 lines
5.5 KiB
Fortran
186 lines
5.5 KiB
Fortran
subroutine htc_bi_ortho_calc_tdav_slow(v, u, N_st, sze)
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use bitmasks
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BEGIN_DOC
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! Application of H_TC on a vector
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!
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! v(i,istate) = \sum_j u(j,istate) H_TC(i,j), with:
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! H_TC(i,j) = < Di | H_TC | Dj >
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!
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END_DOC
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implicit none
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integer, intent(in) :: N_st, sze
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double precision, intent(in) :: u(sze,N_st)
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double precision, intent(inout) :: v(sze,N_st)
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integer :: i, j, istate
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double precision :: htot
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PROVIDE N_int
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PROVIDE psi_det
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! TODO : transform it with the bi-linear representation in terms of alpha-beta.
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i = 1
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j = 1
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call htilde_mu_mat_bi_ortho_tot_slow(psi_det(1,1,i), psi_det(1,1,j), N_int, htot)
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v = 0.d0
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!$OMP PARALLEL DO DEFAULT(NONE) SCHEDULE(dynamic,8) &
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!$OMP SHARED(N_st, sze, N_int, psi_det, u, v) &
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!$OMP PRIVATE(istate, i, j, htot)
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do istate = 1, N_st
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do i = 1, sze
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do j = 1, sze
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call htilde_mu_mat_bi_ortho_tot_slow(psi_det(1,1,i), psi_det(1,1,j), N_int, htot)
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v(i,istate) = v(i,istate) + htot * u(j,istate)
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enddo
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enddo
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enddo
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!$OMP END PARALLEL DO
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end
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subroutine htcdag_bi_ortho_calc_tdav_slow(v, u, N_st, sze)
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use bitmasks
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BEGIN_DOC
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! Application of (H_TC)^dagger on a vector
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!
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! v(i,istate) = \sum_j u(j,istate) H_TC(j,i), with:
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! H_TC(i,j) = < Di | H_TC | Dj >
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!
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END_DOC
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implicit none
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integer, intent(in) :: N_st, sze
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double precision, intent(in) :: u(sze,N_st)
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double precision, intent(inout) :: v(sze,N_st)
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integer :: i, j, istate
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double precision :: htot
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PROVIDE N_int
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PROVIDE psi_det
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i = 1
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j = 1
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call htilde_mu_mat_bi_ortho_tot_slow(psi_det(1,1,i), psi_det(1,1,j), N_int, htot)
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v = 0.d0
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!$OMP PARALLEL DO DEFAULT(NONE) SCHEDULE(dynamic,8) &
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!$OMP SHARED(N_st, sze, N_int, psi_det, u, v) &
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!$OMP PRIVATE(istate, i, j, htot)
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do istate = 1, N_st
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do i = 1, sze
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do j = 1, sze
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call htilde_mu_mat_bi_ortho_tot_slow(psi_det(1,1,j), psi_det(1,1,i), N_int, htot)
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v(i,istate) = v(i,istate) + htot * u(j,istate)
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enddo
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enddo
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enddo
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!$OMP END PARALLEL DO
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end
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subroutine i_H_tc_psi_phi(key,keys,coef_l,coef_r,Nint,Ndet,Ndet_max,Nstate,chi_H_i_array,i_H_phi_array)
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use bitmasks
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implicit none
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BEGIN_DOC
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! Computes $\langle i|H|Phi \rangle = \sum_J c^R_J \langle i | H | J \rangle$.
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!
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! AND $\langle Chi|H| i \rangle = \sum_J c^L_J \langle J | H | i \rangle$.
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!
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! CONVENTION: i_H_phi_array(0) = total matrix element,
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!
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! i_H_phi_array(1) = one-electron matrix element,
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!
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! i_H_phi_array(2) = two-electron matrix element,
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!
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! i_H_phi_array(3) = three-electron matrix element,
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!
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! Uses filter_connected_i_H_psi0 to get all the $|J \rangle$ to which $|i \rangle$
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! is connected.
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!
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! The i_H_psi_minilist is much faster but requires to build the
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! minilists.
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END_DOC
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integer, intent(in) :: Nint, Ndet,Ndet_max,Nstate
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integer(bit_kind), intent(in) :: keys(Nint,2,Ndet)
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integer(bit_kind), intent(in) :: key(Nint,2)
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double precision, intent(in) :: coef_l(Ndet_max,Nstate),coef_r(Ndet_max,Nstate)
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double precision, intent(out) :: chi_H_i_array(0:3,Nstate),i_H_phi_array(0:3,Nstate)
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integer :: i, ii,j
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double precision :: phase
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integer :: exc(0:2,2,2)
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double precision :: hmono, htwoe, hthree, htot
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integer, allocatable :: idx(:)
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ASSERT (Nint > 0)
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ASSERT (N_int == Nint)
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ASSERT (Nstate > 0)
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ASSERT (Ndet > 0)
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ASSERT (Ndet_max >= Ndet)
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allocate(idx(0:Ndet))
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chi_H_i_array = 0.d0
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i_H_phi_array = 0.d0
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call filter_connected_i_H_psi0(keys,key,Nint,Ndet,idx)
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if (Nstate == 1) then
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do ii=1,idx(0)
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i = idx(ii)
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! computes <Chi|H_tc|i>
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!DIR$ FORCEINLINE
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call htilde_mu_mat_opt_bi_ortho(keys(1,1,i), key, Nint, hmono, htwoe, hthree, htot)
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chi_H_i_array(0,1) = chi_H_i_array(0,1) + coef_l(i,1)*htot
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chi_H_i_array(1,1) = chi_H_i_array(1,1) + coef_l(i,1)*hmono
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chi_H_i_array(2,1) = chi_H_i_array(2,1) + coef_l(i,1)*htwoe
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chi_H_i_array(3,1) = chi_H_i_array(3,1) + coef_l(i,1)*hthree
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! computes <i|H_tc|Phi>
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!DIR$ FORCEINLINE
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call htilde_mu_mat_opt_bi_ortho(key,keys(1,1,i), Nint, hmono, htwoe, hthree, htot)
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i_H_phi_array(0,1) = i_H_phi_array(0,1) + coef_r(i,1)*htot
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i_H_phi_array(1,1) = i_H_phi_array(1,1) + coef_r(i,1)*hmono
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i_H_phi_array(2,1) = i_H_phi_array(2,1) + coef_r(i,1)*htwoe
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i_H_phi_array(3,1) = i_H_phi_array(3,1) + coef_r(i,1)*hthree
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enddo
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else
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do ii=1,idx(0)
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i = idx(ii)
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! computes <Chi|H_tc|i>
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!DIR$ FORCEINLINE
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call htilde_mu_mat_opt_bi_ortho(keys(1,1,i), key, Nint, hmono, htwoe, hthree, htot)
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do j = 1, Nstate
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chi_H_i_array(0,j) = chi_H_i_array(0,j) + coef_l(i,j)*htot
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chi_H_i_array(1,j) = chi_H_i_array(1,j) + coef_l(i,j)*hmono
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chi_H_i_array(2,j) = chi_H_i_array(2,j) + coef_l(i,j)*htwoe
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chi_H_i_array(3,j) = chi_H_i_array(3,j) + coef_l(i,j)*hthree
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enddo
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! computes <i|H_tc|Phi>
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!DIR$ FORCEINLINE
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call htilde_mu_mat_opt_bi_ortho(key,keys(1,1,i), Nint, hmono, htwoe, hthree, htot)
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do j = 1, Nstate
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i_H_phi_array(0,j) = i_H_phi_array(0,j) + coef_r(i,j)*htot
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i_H_phi_array(1,j) = i_H_phi_array(1,j) + coef_r(i,j)*hmono
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i_H_phi_array(2,j) = i_H_phi_array(2,j) + coef_r(i,j)*htwoe
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i_H_phi_array(3,j) = i_H_phi_array(3,j) + coef_r(i,j)*hthree
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enddo
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enddo
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endif
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end
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