mirror of
https://github.com/QuantumPackage/qp2.git
synced 2024-10-06 16:15:57 +02:00
575 lines
20 KiB
Fortran
575 lines
20 KiB
Fortran
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! ---
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BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du_0, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du_x, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du_y, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du_z, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du_2, (ao_num, ao_num, n_points_final_grid)]
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BEGIN_DOC
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!
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! Ir2_Mu_long_Du_0 = int dr2 phi_i(r2) phi_j(r2) fc_env(r2) [(1 - erf(mu r_12) / r_12]
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!
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! Ir2_Mu_long_Du_x = int dr2 phi_i(r2) phi_j(r2) fc_env(r2) [(1 - erf(mu r_12) / r_12] * x2
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! Ir2_Mu_long_Du_y = int dr2 phi_i(r2) phi_j(r2) fc_env(r2) [(1 - erf(mu r_12) / r_12] * y2
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! Ir2_Mu_long_Du_z = int dr2 phi_i(r2) phi_j(r2) fc_env(r2) [(1 - erf(mu r_12) / r_12] * z2
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!
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! Ir2_Mu_long_Du_2 = int dr2 phi_i(r2) phi_j(r2) fc_env(r2) [(1 - erf(mu r_12) / r_12] * r2^2
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!
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END_DOC
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implicit none
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integer :: i, j, ipoint, i_1s
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double precision :: r(3), int_clb(7), int_erf(7)
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double precision :: c_1s, e_1s, R_1s(3)
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double precision :: tmp_Du_0, tmp_Du_x, tmp_Du_y, tmp_Du_z, tmp_Du_2
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double precision :: wall0, wall1
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PROVIDE mu_erf
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PROVIDE final_grid_points
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PROVIDE List_env1s_size List_env1s_expo List_env1s_coef List_env1s_cent
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print *, ' providing Ir2_Mu_long_Du ...'
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call wall_time(wall0)
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!$OMP PARALLEL DEFAULT (NONE) &
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!$OMP PRIVATE (ipoint, i, j, i_1s, r, c_1s, e_1s, R_1s, int_erf, int_clb, &
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!$OMP tmp_Du_0, tmp_Du_x, tmp_Du_y, tmp_Du_z, tmp_Du_2) &
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!$OMP SHARED (n_points_final_grid, ao_num, final_grid_points, mu_erf, &
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!$OMP List_env1s_size, List_env1s_expo, &
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!$OMP List_env1s_coef, List_env1s_cent, &
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!$OMP Ir2_Mu_long_Du_0, Ir2_Mu_long_Du_x, &
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!$OMP Ir2_Mu_long_Du_y, Ir2_Mu_long_Du_z, &
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!$OMP Ir2_Mu_long_Du_2)
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!$OMP DO
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do ipoint = 1, n_points_final_grid
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r(1) = final_grid_points(1,ipoint)
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r(2) = final_grid_points(2,ipoint)
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r(3) = final_grid_points(3,ipoint)
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do i = 1, ao_num
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do j = i, ao_num
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call NAI_pol_012_mult_erf_ao(i, j, 1.d+9, r, int_clb)
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call NAI_pol_012_mult_erf_ao(i, j, mu_erf, r, int_erf)
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tmp_Du_0 = int_clb(1) - int_erf(1)
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tmp_Du_x = int_clb(2) - int_erf(2)
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tmp_Du_y = int_clb(3) - int_erf(3)
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tmp_Du_z = int_clb(4) - int_erf(4)
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tmp_Du_2 = int_clb(5) + int_clb(6) + int_clb(7) - int_erf(5) - int_erf(6) - int_erf(7)
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do i_1s = 2, List_env1s_size
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e_1s = List_env1s_expo(i_1s)
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c_1s = List_env1s_coef(i_1s)
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R_1s(1) = List_env1s_cent(1,i_1s)
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R_1s(2) = List_env1s_cent(2,i_1s)
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R_1s(3) = List_env1s_cent(3,i_1s)
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call NAI_pol_012_mult_erf_ao_with1s(i, j, e_1s, R_1s, 1.d+9, r, int_clb)
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call NAI_pol_012_mult_erf_ao_with1s(i, j, e_1s, R_1s, mu_erf, r, int_erf)
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tmp_Du_0 = tmp_Du_0 + c_1s * (int_clb(1) - int_erf(1))
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tmp_Du_x = tmp_Du_x + c_1s * (int_clb(2) - int_erf(2))
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tmp_Du_y = tmp_Du_y + c_1s * (int_clb(3) - int_erf(3))
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tmp_Du_z = tmp_Du_z + c_1s * (int_clb(4) - int_erf(4))
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tmp_Du_2 = tmp_Du_2 + c_1s * (int_clb(5) + int_clb(6) + int_clb(7) - int_erf(5) - int_erf(6) - int_erf(7))
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enddo
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Ir2_Mu_long_Du_0(j,i,ipoint) = tmp_Du_0
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Ir2_Mu_long_Du_x(j,i,ipoint) = tmp_Du_x
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Ir2_Mu_long_Du_y(j,i,ipoint) = tmp_Du_y
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Ir2_Mu_long_Du_z(j,i,ipoint) = tmp_Du_z
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Ir2_Mu_long_Du_2(j,i,ipoint) = tmp_Du_2
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enddo
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enddo
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enddo
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!$OMP END DO
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!$OMP END PARALLEL
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do ipoint = 1, n_points_final_grid
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do i = 2, ao_num
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do j = 1, i-1
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Ir2_Mu_long_Du_0(j,i,ipoint) = Ir2_Mu_long_Du_0(i,j,ipoint)
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Ir2_Mu_long_Du_x(j,i,ipoint) = Ir2_Mu_long_Du_x(i,j,ipoint)
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Ir2_Mu_long_Du_y(j,i,ipoint) = Ir2_Mu_long_Du_y(i,j,ipoint)
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Ir2_Mu_long_Du_z(j,i,ipoint) = Ir2_Mu_long_Du_z(i,j,ipoint)
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Ir2_Mu_long_Du_2(j,i,ipoint) = Ir2_Mu_long_Du_2(i,j,ipoint)
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enddo
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enddo
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enddo
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call wall_time(wall1)
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print*, ' wall time for Ir2_Mu_long_Du (min) = ', (wall1 - wall0) / 60.d0
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END_PROVIDER
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! ---
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BEGIN_PROVIDER [double precision, Ir2_Mu_gauss_Du, (ao_num, ao_num, n_points_final_grid)]
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BEGIN_DOC
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!
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! Ir2_Mu_gauss_Du = int dr2 phi_i(r2) phi_j(r2) fc_env(r2) e^{-(mu r_12)^2}
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!
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END_DOC
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implicit none
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integer :: i, j, ipoint, i_1s
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double precision :: r(3)
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double precision :: coef, beta, B_center(3)
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double precision :: tmp_Du
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double precision :: mu_sq, dx, dy, dz, tmp_arg, rmu_sq(3)
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double precision :: e_1s, c_1s, R_1s(3)
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double precision :: wall0, wall1
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double precision, external :: overlap_gauss_r12_ao
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PROVIDE mu_erf
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PROVIDE final_grid_points
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PROVIDE List_env1s_size List_env1s_expo List_env1s_coef List_env1s_cent
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print *, ' providing Ir2_Mu_gauss_Du ...'
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call wall_time(wall0)
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mu_sq = mu_erf * mu_erf
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!$OMP PARALLEL DEFAULT (NONE) &
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!$OMP PRIVATE (ipoint, i, j, i_1s, dx, dy, dz, r, tmp_arg, coef, &
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!$OMP rmu_sq, e_1s, c_1s, R_1s, beta, B_center, tmp_Du) &
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!$OMP SHARED (n_points_final_grid, ao_num, final_grid_points, mu_sq, &
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!$OMP List_env1s_size, List_env1s_expo, &
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!$OMP List_env1s_coef, List_env1s_cent, &
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!$OMP Ir2_Mu_gauss_Du)
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!$OMP DO
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do ipoint = 1, n_points_final_grid
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r(1) = final_grid_points(1,ipoint)
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r(2) = final_grid_points(2,ipoint)
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r(3) = final_grid_points(3,ipoint)
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rmu_sq(1) = mu_sq * r(1)
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rmu_sq(2) = mu_sq * r(2)
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rmu_sq(3) = mu_sq * r(3)
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do i = 1, ao_num
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do j = i, ao_num
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tmp_Du = overlap_gauss_r12_ao(r, mu_sq, j, i)
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do i_1s = 2, List_env1s_size
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e_1s = List_env1s_expo(i_1s)
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c_1s = List_env1s_coef(i_1s)
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R_1s(1) = List_env1s_cent(1,i_1s)
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R_1s(2) = List_env1s_cent(2,i_1s)
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R_1s(3) = List_env1s_cent(3,i_1s)
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dx = r(1) - R_1s(1)
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dy = r(2) - R_1s(2)
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dz = r(3) - R_1s(3)
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beta = mu_sq + e_1s
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tmp_arg = mu_sq * e_1s * (dx*dx + dy*dy + dz*dz) / beta
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coef = c_1s * dexp(-tmp_arg)
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B_center(1) = (rmu_sq(1) + e_1s * R_1s(1)) / beta
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B_center(2) = (rmu_sq(2) + e_1s * R_1s(2)) / beta
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B_center(3) = (rmu_sq(3) + e_1s * R_1s(3)) / beta
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tmp_Du += coef * overlap_gauss_r12_ao(B_center, beta, j, i)
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enddo
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Ir2_Mu_gauss_Du(j,i,ipoint) = tmp_Du
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enddo
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enddo
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enddo
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!$OMP END DO
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!$OMP END PARALLEL
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do ipoint = 1, n_points_final_grid
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do i = 2, ao_num
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do j = 1, i-1
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Ir2_Mu_gauss_Du(j,i,ipoint) = Ir2_Mu_gauss_Du(i,j,ipoint)
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enddo
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enddo
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enddo
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call wall_time(wall1)
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print*, ' wall time for Ir2_Mu_gauss_Du (min) = ', (wall1 - wall0) / 60.d0
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END_PROVIDER
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! ---
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BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du2_0, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du2_x, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du2_y, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du2_z, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_long_Du2_2, (ao_num, ao_num, n_points_final_grid)]
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BEGIN_DOC
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!
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! Ir2_Mu_long_Du2_0 = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12) / r_12]
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!
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! Ir2_Mu_long_Du2_x = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12) / r_12] * x2
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! Ir2_Mu_long_Du2_y = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12) / r_12] * y2
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! Ir2_Mu_long_Du2_z = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12) / r_12] * z2
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!
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! Ir2_Mu_long_Du2_2 = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12) / r_12] * r2^2
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!
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END_DOC
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implicit none
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integer :: i, j, ipoint, i_1s
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double precision :: r(3), int_clb(7), int_erf(7)
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double precision :: coef, beta, B_center(3)
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double precision :: tmp_Du2_0, tmp_Du2_x, tmp_Du2_y, tmp_Du2_z, tmp_Du2_2
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double precision :: mu_sq, tmp_arg, dx, dy, dz, rmu_sq(3)
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double precision :: e_1s, c_1s, R_1s(3)
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double precision :: wall0, wall1
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PROVIDE mu_erf
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PROVIDE final_grid_points
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PROVIDE List_env1s_square_size List_env1s_square_expo List_env1s_square_coef List_env1s_square_cent
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print *, ' providing Ir2_Mu_long_Du2 ...'
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call wall_time(wall0)
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mu_sq = mu_erf * mu_erf
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!$OMP PARALLEL DEFAULT (NONE) &
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!$OMP PRIVATE (ipoint, i, j, i_1s, r, rmu_sq, dx, dy, dz, &
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!$OMP e_1s, c_1s, R_1s, tmp_arg, coef, beta, B_center, &
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!$OMP int_erf, int_clb, &
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!$OMP tmp_Du2_0, tmp_Du2_x, tmp_Du2_y, tmp_Du2_z, tmp_Du2_2) &
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!$OMP SHARED (n_points_final_grid, ao_num, final_grid_points, mu_sq, &
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!$OMP mu_erf, List_env1s_square_size, List_env1s_square_expo, &
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!$OMP List_env1s_square_coef, List_env1s_square_cent, &
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!$OMP Ir2_Mu_long_Du2_0, Ir2_Mu_long_Du2_x, &
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!$OMP Ir2_Mu_long_Du2_y, Ir2_Mu_long_Du2_z, &
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!$OMP Ir2_Mu_long_Du2_2)
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!$OMP DO
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do ipoint = 1, n_points_final_grid
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r(1) = final_grid_points(1,ipoint)
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r(2) = final_grid_points(2,ipoint)
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r(3) = final_grid_points(3,ipoint)
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rmu_sq(1) = mu_sq * r(1)
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rmu_sq(2) = mu_sq * r(2)
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rmu_sq(3) = mu_sq * r(3)
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do i = 1, ao_num
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do j = i, ao_num
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call NAI_pol_012_mult_erf_ao_with1s(i, j, mu_sq, r, 1.d+9, r, int_clb)
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call NAI_pol_012_mult_erf_ao_with1s(i, j, mu_sq, r, mu_erf, r, int_erf)
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tmp_Du2_0 = int_clb(1) - int_erf(1)
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tmp_Du2_x = int_clb(2) - int_erf(2)
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tmp_Du2_y = int_clb(3) - int_erf(3)
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tmp_Du2_z = int_clb(4) - int_erf(4)
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tmp_Du2_2 = int_clb(5) + int_clb(6) + int_clb(7) - int_erf(5) - int_erf(6) - int_erf(7)
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do i_1s = 2, List_env1s_square_size
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e_1s = List_env1s_square_expo(i_1s)
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c_1s = List_env1s_square_coef(i_1s)
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R_1s(1) = List_env1s_square_cent(1,i_1s)
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R_1s(2) = List_env1s_square_cent(2,i_1s)
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R_1s(3) = List_env1s_square_cent(3,i_1s)
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dx = r(1) - R_1s(1)
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dy = r(2) - R_1s(2)
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dz = r(3) - R_1s(3)
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beta = mu_sq + e_1s
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tmp_arg = mu_sq * e_1s * (dx*dx + dy*dy + dz*dz) / beta
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coef = c_1s * dexp(-tmp_arg)
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B_center(1) = (rmu_sq(1) + e_1s * R_1s(1)) / beta
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B_center(2) = (rmu_sq(2) + e_1s * R_1s(2)) / beta
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B_center(3) = (rmu_sq(3) + e_1s * R_1s(3)) / beta
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call NAI_pol_012_mult_erf_ao_with1s(i, j, beta, B_center, 1.d+9, r, int_clb)
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call NAI_pol_012_mult_erf_ao_with1s(i, j, beta, B_center, mu_erf, r, int_erf)
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tmp_Du2_0 = tmp_Du2_0 + coef * (int_clb(1) - int_erf(1))
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tmp_Du2_x = tmp_Du2_x + coef * (int_clb(2) - int_erf(2))
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tmp_Du2_y = tmp_Du2_y + coef * (int_clb(3) - int_erf(3))
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tmp_Du2_z = tmp_Du2_z + coef * (int_clb(4) - int_erf(4))
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tmp_Du2_2 = tmp_Du2_2 + coef * (int_clb(5) + int_clb(6) + int_clb(7) - int_erf(5) - int_erf(6) - int_erf(7))
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enddo
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Ir2_Mu_long_Du2_0(j,i,ipoint) = tmp_Du2_0
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Ir2_Mu_long_Du2_x(j,i,ipoint) = tmp_Du2_x
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Ir2_Mu_long_Du2_y(j,i,ipoint) = tmp_Du2_y
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Ir2_Mu_long_Du2_z(j,i,ipoint) = tmp_Du2_z
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Ir2_Mu_long_Du2_2(j,i,ipoint) = tmp_Du2_2
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enddo
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enddo
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enddo
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!$OMP END DO
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!$OMP END PARALLEL
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do ipoint = 1, n_points_final_grid
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do i = 2, ao_num
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do j = 1, i-1
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Ir2_Mu_long_Du2_0(j,i,ipoint) = Ir2_Mu_long_Du2_0(i,j,ipoint)
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Ir2_Mu_long_Du2_x(j,i,ipoint) = Ir2_Mu_long_Du2_x(i,j,ipoint)
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Ir2_Mu_long_Du2_y(j,i,ipoint) = Ir2_Mu_long_Du2_y(i,j,ipoint)
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Ir2_Mu_long_Du2_z(j,i,ipoint) = Ir2_Mu_long_Du2_z(i,j,ipoint)
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Ir2_Mu_long_Du2_2(j,i,ipoint) = Ir2_Mu_long_Du2_2(i,j,ipoint)
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enddo
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enddo
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enddo
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call wall_time(wall1)
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print*, ' wall time for Ir2_Mu_long_Du2 (min) = ', (wall1 - wall0) / 60.d0
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END_PROVIDER
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! ---
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BEGIN_PROVIDER [double precision, Ir2_Mu_gauss_Du2, (ao_num, ao_num, n_points_final_grid)]
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BEGIN_DOC
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!
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! Ir2_Mu_gauss_Du2 = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 e^{-(mu r_12)^2}
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!
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END_DOC
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implicit none
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integer :: i, j, ipoint, i_1s
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double precision :: r(3)
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double precision :: coef, beta, B_center(3)
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double precision :: tmp_Du2
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double precision :: mu_sq, dx, dy, dz, tmp_arg, rmu_sq(3)
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double precision :: e_1s, c_1s, R_1s(3)
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double precision :: wall0, wall1
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double precision, external :: overlap_gauss_r12_ao
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PROVIDE mu_erf
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PROVIDE final_grid_points
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PROVIDE List_env1s_square_size List_env1s_square_expo List_env1s_square_coef List_env1s_square_cent
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print *, ' providing Ir2_Mu_gauss_Du2 ...'
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call wall_time(wall0)
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mu_sq = 2.d0 * mu_erf * mu_erf
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!$OMP PARALLEL DEFAULT (NONE) &
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!$OMP PRIVATE (ipoint, i, j, i_1s, dx, dy, dz, r, tmp_arg, coef, &
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!$OMP rmu_sq, e_1s, c_1s, R_1s, beta, B_center, tmp_Du2) &
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!$OMP SHARED (n_points_final_grid, ao_num, final_grid_points, mu_sq, &
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!$OMP List_env1s_square_size, List_env1s_square_expo, &
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!$OMP List_env1s_square_coef, List_env1s_square_cent, &
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!$OMP Ir2_Mu_gauss_Du2)
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!$OMP DO
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do ipoint = 1, n_points_final_grid
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r(1) = final_grid_points(1,ipoint)
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r(2) = final_grid_points(2,ipoint)
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r(3) = final_grid_points(3,ipoint)
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rmu_sq(1) = mu_sq * r(1)
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rmu_sq(2) = mu_sq * r(2)
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rmu_sq(3) = mu_sq * r(3)
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do i = 1, ao_num
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do j = i, ao_num
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tmp_Du2 = overlap_gauss_r12_ao(r, mu_sq, j, i)
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do i_1s = 2, List_env1s_square_size
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e_1s = List_env1s_square_expo(i_1s)
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c_1s = List_env1s_square_coef(i_1s)
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R_1s(1) = List_env1s_square_cent(1,i_1s)
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R_1s(2) = List_env1s_square_cent(2,i_1s)
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R_1s(3) = List_env1s_square_cent(3,i_1s)
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dx = r(1) - R_1s(1)
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dy = r(2) - R_1s(2)
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dz = r(3) - R_1s(3)
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beta = mu_sq + e_1s
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tmp_arg = mu_sq * e_1s * (dx*dx + dy*dy + dz*dz) / beta
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coef = c_1s * dexp(-tmp_arg)
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B_center(1) = (rmu_sq(1) + e_1s * R_1s(1)) / beta
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B_center(2) = (rmu_sq(2) + e_1s * R_1s(2)) / beta
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B_center(3) = (rmu_sq(3) + e_1s * R_1s(3)) / beta
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tmp_Du2 += coef * overlap_gauss_r12_ao(B_center, beta, j, i)
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enddo
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Ir2_Mu_gauss_Du2(j,i,ipoint) = tmp_Du2
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enddo
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enddo
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enddo
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!$OMP END DO
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!$OMP END PARALLEL
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do ipoint = 1, n_points_final_grid
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do i = 2, ao_num
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do j = 1, i-1
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Ir2_Mu_gauss_Du2(j,i,ipoint) = Ir2_Mu_gauss_Du2(i,j,ipoint)
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enddo
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enddo
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enddo
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call wall_time(wall1)
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print*, ' wall time for Ir2_Mu_gauss_Du2 (min) = ', (wall1 - wall0) / 60.d0
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END_PROVIDER
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! ---
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BEGIN_PROVIDER [double precision, Ir2_Mu_short_Du2_0, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_short_Du2_x, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_short_Du2_y, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_short_Du2_z, (ao_num, ao_num, n_points_final_grid)]
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&BEGIN_PROVIDER [double precision, Ir2_Mu_short_Du2_2, (ao_num, ao_num, n_points_final_grid)]
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BEGIN_DOC
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!
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! Ir2_Mu_short_Du2_0 = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12)]^2
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!
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! Ir2_Mu_short_Du2_x = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12)]^2 * x2
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! Ir2_Mu_short_Du2_y = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12)]^2 * y2
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! Ir2_Mu_short_Du2_z = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12)]^2 * z2
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!
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! Ir2_Mu_short_Du2_2 = int dr2 phi_i(r2) phi_j(r2) [fc_env(r2)]^2 [(1 - erf(mu r_12)]^2 * r2^2
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!
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END_DOC
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implicit none
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integer :: i, j, ipoint, i_1s, i_fit
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double precision :: r(3), ints(7)
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double precision :: coef, beta, B_center(3)
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double precision :: tmp_Du2_0, tmp_Du2_x, tmp_Du2_y, tmp_Du2_z, tmp_Du2_2
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double precision :: tmp_arg, dx, dy, dz
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double precision :: expo_fit, coef_fit, e_1s, c_1s, R_1s(3)
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double precision :: wall0, wall1
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PROVIDE final_grid_points
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PROVIDE List_env1s_square_size List_env1s_square_expo List_env1s_square_coef List_env1s_square_cent
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PROVIDE ng_fit_jast expo_gauss_1_erf_x_2 coef_gauss_1_erf_x_2
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print *, ' providing Ir2_Mu_short_Du2 ...'
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call wall_time(wall0)
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!$OMP PARALLEL DEFAULT (NONE) &
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!$OMP PRIVATE (ipoint, i, j, i_1s, i_fit, r, dx, dy, dz, &
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!$OMP expo_fit, coef_fit, e_1s, c_1s, R_1s, &
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!$OMP tmp_arg, coef, beta, B_center, ints, &
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!$OMP tmp_Du2_0, tmp_Du2_x, tmp_Du2_y, tmp_Du2_z, tmp_Du2_2) &
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!$OMP SHARED (n_points_final_grid, ao_num, final_grid_points, &
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!$OMP ng_fit_jast, expo_gauss_1_erf_x_2, coef_gauss_1_erf_x_2, &
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!$OMP List_env1s_square_size, List_env1s_square_expo, &
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!$OMP List_env1s_square_coef, List_env1s_square_cent, &
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!$OMP Ir2_Mu_short_Du2_0, Ir2_Mu_short_Du2_x, &
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!$OMP Ir2_Mu_short_Du2_y, Ir2_Mu_short_Du2_z, &
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!$OMP Ir2_Mu_short_Du2_2)
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!$OMP DO
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do ipoint = 1, n_points_final_grid
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r(1) = final_grid_points(1,ipoint)
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r(2) = final_grid_points(2,ipoint)
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r(3) = final_grid_points(3,ipoint)
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do i = 1, ao_num
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do j = i, ao_num
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tmp_Du2_0 = 0.d0
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tmp_Du2_x = 0.d0
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tmp_Du2_y = 0.d0
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tmp_Du2_z = 0.d0
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tmp_Du2_2 = 0.d0
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do i_fit = 1, ng_fit_jast
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expo_fit = expo_gauss_1_erf_x_2(i_fit)
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coef_fit = coef_gauss_1_erf_x_2(i_fit)
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call overlap_gauss_r12_ao_012(r, expo_fit, i, j, ints)
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tmp_Du2_0 += coef_fit * ints(1)
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tmp_Du2_x += coef_fit * ints(2)
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tmp_Du2_y += coef_fit * ints(3)
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tmp_Du2_z += coef_fit * ints(4)
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tmp_Du2_2 += coef_fit * (ints(5) + ints(6) + ints(7))
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do i_1s = 2, List_env1s_square_size
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e_1s = List_env1s_square_expo(i_1s)
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c_1s = List_env1s_square_coef(i_1s)
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R_1s(1) = List_env1s_square_cent(1,i_1s)
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R_1s(2) = List_env1s_square_cent(2,i_1s)
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R_1s(3) = List_env1s_square_cent(3,i_1s)
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dx = r(1) - R_1s(1)
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dy = r(2) - R_1s(2)
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dz = r(3) - R_1s(3)
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beta = expo_fit + e_1s
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tmp_arg = expo_fit * e_1s * (dx*dx + dy*dy + dz*dz) / beta
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coef = coef_fit * c_1s * dexp(-tmp_arg)
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B_center(1) = (expo_fit * r(1) + e_1s * R_1s(1)) / beta
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B_center(2) = (expo_fit * r(2) + e_1s * R_1s(2)) / beta
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B_center(3) = (expo_fit * r(3) + e_1s * R_1s(3)) / beta
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call overlap_gauss_r12_ao_012(B_center, beta, i, j, ints)
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tmp_Du2_0 += coef * ints(1)
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tmp_Du2_x += coef * ints(2)
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tmp_Du2_y += coef * ints(3)
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tmp_Du2_z += coef * ints(4)
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tmp_Du2_2 += coef * (ints(5) + ints(6) + ints(7))
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enddo ! i_1s
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enddo ! i_fit
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Ir2_Mu_short_Du2_0(j,i,ipoint) = tmp_Du2_0
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Ir2_Mu_short_Du2_x(j,i,ipoint) = tmp_Du2_x
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Ir2_Mu_short_Du2_y(j,i,ipoint) = tmp_Du2_y
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Ir2_Mu_short_Du2_z(j,i,ipoint) = tmp_Du2_z
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Ir2_Mu_short_Du2_2(j,i,ipoint) = tmp_Du2_2
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enddo ! j
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enddo ! i
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enddo ! ipoint
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!$OMP END DO
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!$OMP END PARALLEL
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do ipoint = 1, n_points_final_grid
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do i = 2, ao_num
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do j = 1, i-1
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Ir2_Mu_short_Du2_0(j,i,ipoint) = Ir2_Mu_short_Du2_0(i,j,ipoint)
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Ir2_Mu_short_Du2_x(j,i,ipoint) = Ir2_Mu_short_Du2_x(i,j,ipoint)
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Ir2_Mu_short_Du2_y(j,i,ipoint) = Ir2_Mu_short_Du2_y(i,j,ipoint)
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Ir2_Mu_short_Du2_z(j,i,ipoint) = Ir2_Mu_short_Du2_z(i,j,ipoint)
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Ir2_Mu_short_Du2_2(j,i,ipoint) = Ir2_Mu_short_Du2_2(i,j,ipoint)
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enddo
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enddo
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enddo
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call wall_time(wall1)
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print*, ' wall time for Ir2_Mu_short_Du2 (min) = ', (wall1 - wall0) / 60.d0
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END_PROVIDER
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! ---
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