qp2/src/ao_many_one_e_ints/listj1b.irp.f


! ---

BEGIN_PROVIDER [ integer, List_all_comb_b2_size]

  implicit none

  List_all_comb_b2_size = 2**nucl_num

END_PROVIDER

! ---

BEGIN_PROVIDER [ integer, List_all_comb_b2, (nucl_num, List_all_comb_b2_size)]

  implicit none
  integer :: i, j

  if(nucl_num .gt. 32) then
    print *, ' nucl_num = ', nucl_num, '> 32'
    stop
  endif

  List_all_comb_b2 = 0

  do i = 0, List_all_comb_b2_size-1
    do j = 0, nucl_num-1
      if (btest(i,j)) then
        List_all_comb_b2(j+1,i+1) = 1
      endif
    enddo
  enddo

END_PROVIDER

! ---

 BEGIN_PROVIDER [ double precision, List_all_comb_b2_coef, (   List_all_comb_b2_size)]
&BEGIN_PROVIDER [ double precision, List_all_comb_b2_expo, (   List_all_comb_b2_size)]
&BEGIN_PROVIDER [ double precision, List_all_comb_b2_cent, (3, List_all_comb_b2_size)]

  implicit none
  integer          :: i, j, k, phase
  double precision :: tmp_alphaj, tmp_alphak
  double precision :: tmp_cent_x, tmp_cent_y, tmp_cent_z

  provide j1b_pen

  List_all_comb_b2_coef = 0.d0
  List_all_comb_b2_expo = 0.d0
  List_all_comb_b2_cent = 0.d0

  do i = 1, List_all_comb_b2_size

    tmp_cent_x = 0.d0
    tmp_cent_y = 0.d0
    tmp_cent_z = 0.d0
    do j = 1, nucl_num
      tmp_alphaj = dble(List_all_comb_b2(j,i)) * j1b_pen(j)
      List_all_comb_b2_expo(i) += tmp_alphaj
      tmp_cent_x               += tmp_alphaj * nucl_coord(j,1)
      tmp_cent_y               += tmp_alphaj * nucl_coord(j,2)
      tmp_cent_z               += tmp_alphaj * nucl_coord(j,3)
    enddo

    if(List_all_comb_b2_expo(i) .lt. 1d-10) cycle

    List_all_comb_b2_cent(1,i) = tmp_cent_x / List_all_comb_b2_expo(i) 
    List_all_comb_b2_cent(2,i) = tmp_cent_y / List_all_comb_b2_expo(i)
    List_all_comb_b2_cent(3,i) = tmp_cent_z / List_all_comb_b2_expo(i)
  enddo

  ! ---

  do i = 1, List_all_comb_b2_size

    do j = 2, nucl_num, 1
      tmp_alphaj = dble(List_all_comb_b2(j,i)) * j1b_pen(j)
      do k = 1, j-1, 1
        tmp_alphak = dble(List_all_comb_b2(k,i)) * j1b_pen(k)

        List_all_comb_b2_coef(i) += tmp_alphaj * tmp_alphak * ( (nucl_coord(j,1) - nucl_coord(k,1)) * (nucl_coord(j,1) - nucl_coord(k,1)) &
                                                              + (nucl_coord(j,2) - nucl_coord(k,2)) * (nucl_coord(j,2) - nucl_coord(k,2)) &
                                                              + (nucl_coord(j,3) - nucl_coord(k,3)) * (nucl_coord(j,3) - nucl_coord(k,3)) )
      enddo
    enddo

    if(List_all_comb_b2_expo(i) .lt. 1d-10) cycle

    List_all_comb_b2_coef(i) = List_all_comb_b2_coef(i) / List_all_comb_b2_expo(i)
  enddo

  ! ---

  do i = 1, List_all_comb_b2_size

    phase = 0
    do j = 1, nucl_num
      phase += List_all_comb_b2(j,i)
    enddo

    List_all_comb_b2_coef(i) = (-1.d0)**dble(phase) * dexp(-List_all_comb_b2_coef(i))
  enddo

  !print *, ' coeff, expo & cent of list b2'
  !do i = 1, List_all_comb_b2_size
  !  print*, i, List_all_comb_b2_coef(i), List_all_comb_b2_expo(i)
  !  print*, List_all_comb_b2_cent(1,i), List_all_comb_b2_cent(2,i), List_all_comb_b2_cent(3,i)
  !enddo

END_PROVIDER

! ---

BEGIN_PROVIDER [ integer, List_all_comb_b3_size]

  implicit none

  List_all_comb_b3_size = 3**nucl_num

END_PROVIDER

! ---

BEGIN_PROVIDER [ integer, List_all_comb_b3, (nucl_num, List_all_comb_b3_size)]

  implicit none
  integer              :: i, j, ii, jj
  integer, allocatable :: M(:,:), p(:)

  if(nucl_num .gt. 32) then
    print *, ' nucl_num = ', nucl_num, '> 32'
    stop
  endif

  List_all_comb_b3(:,:)                     = 0
  List_all_comb_b3(:,List_all_comb_b3_size) = 2

  allocate(p(nucl_num))
  p = 0

  do i = 2, List_all_comb_b3_size-1
    do j = 1, nucl_num

      ii = 0
      do jj = 1, j-1, 1
        ii = ii + p(jj) * 3**(jj-1)
      enddo
      p(j) = modulo(i-1-ii, 3**j) / 3**(j-1)

      List_all_comb_b3(j,i) = p(j)
    enddo
  enddo

END_PROVIDER

! ---

 BEGIN_PROVIDER [ double precision, List_all_comb_b3_coef, (   List_all_comb_b3_size)]
&BEGIN_PROVIDER [ double precision, List_all_comb_b3_expo, (   List_all_comb_b3_size)]
&BEGIN_PROVIDER [ double precision, List_all_comb_b3_cent, (3, List_all_comb_b3_size)]

  implicit none
  integer          :: i, j, k, phase
  double precision :: tmp_alphaj, tmp_alphak, facto

  provide j1b_pen

  List_all_comb_b3_coef = 0.d0
  List_all_comb_b3_expo = 0.d0
  List_all_comb_b3_cent = 0.d0

  do i = 1, List_all_comb_b3_size

    do j = 1, nucl_num
      tmp_alphaj = dble(List_all_comb_b3(j,i)) * j1b_pen(j)
      List_all_comb_b3_expo(i)   += tmp_alphaj
      List_all_comb_b3_cent(1,i) += tmp_alphaj * nucl_coord(j,1)
      List_all_comb_b3_cent(2,i) += tmp_alphaj * nucl_coord(j,2)
      List_all_comb_b3_cent(3,i) += tmp_alphaj * nucl_coord(j,3)

    enddo

    if(List_all_comb_b3_expo(i) .lt. 1d-10) cycle
    ASSERT(List_all_comb_b3_expo(i) .gt. 0d0)

    List_all_comb_b3_cent(1,i) = List_all_comb_b3_cent(1,i) / List_all_comb_b3_expo(i) 
    List_all_comb_b3_cent(2,i) = List_all_comb_b3_cent(2,i) / List_all_comb_b3_expo(i)
    List_all_comb_b3_cent(3,i) = List_all_comb_b3_cent(3,i) / List_all_comb_b3_expo(i)
  enddo

  ! ---

  do i = 1, List_all_comb_b3_size

    do j = 2, nucl_num, 1
      tmp_alphaj = dble(List_all_comb_b3(j,i)) * j1b_pen(j)
      do k = 1, j-1, 1
        tmp_alphak = dble(List_all_comb_b3(k,i)) * j1b_pen(k)

        List_all_comb_b3_coef(i) += tmp_alphaj * tmp_alphak * ( (nucl_coord(j,1) - nucl_coord(k,1)) * (nucl_coord(j,1) - nucl_coord(k,1)) &
                                                              + (nucl_coord(j,2) - nucl_coord(k,2)) * (nucl_coord(j,2) - nucl_coord(k,2)) &
                                                              + (nucl_coord(j,3) - nucl_coord(k,3)) * (nucl_coord(j,3) - nucl_coord(k,3)) )
      enddo
    enddo

    if(List_all_comb_b3_expo(i) .lt. 1d-10) cycle

    List_all_comb_b3_coef(i) = List_all_comb_b3_coef(i) / List_all_comb_b3_expo(i)
  enddo

  ! ---

  do i = 1, List_all_comb_b3_size

    facto = 1.d0
    phase = 0
    do j = 1, nucl_num
      tmp_alphaj = dble(List_all_comb_b3(j,i)) 

      facto *= 2.d0 / (gamma(tmp_alphaj+1.d0) * gamma(3.d0-tmp_alphaj))
      phase += List_all_comb_b3(j,i)
    enddo

    List_all_comb_b3_coef(i) = (-1.d0)**dble(phase) * facto * dexp(-List_all_comb_b3_coef(i))
  enddo

  !print *, ' coeff, expo & cent of list b3'
  !do i = 1, List_all_comb_b3_size
  !  print*, i, List_all_comb_b3_coef(i), List_all_comb_b3_expo(i)
  !  print*, List_all_comb_b3_cent(1,i), List_all_comb_b3_cent(2,i), List_all_comb_b3_cent(3,i)
  !enddo

END_PROVIDER

! ---
added ao_many_one_e_ints/ bi_ortho_mos/ 2023-02-06 18:17:56 +01:00
			`! ---`

			`BEGIN_PROVIDER [ integer, List_all_comb_b2_size]`

			`implicit none`

			`List_all_comb_b2_size = 2**nucl_num`

			`END_PROVIDER`

			`! ---`

			`BEGIN_PROVIDER [ integer, List_all_comb_b2, (nucl_num, List_all_comb_b2_size)]`

			`implicit none`
			`integer :: i, j`

			`if(nucl_num .gt. 32) then`
			`print *, ' nucl_num = ', nucl_num, '> 32'`
			`stop`
			`endif`

			`List_all_comb_b2 = 0`

			`do i = 0, List_all_comb_b2_size-1`
			`do j = 0, nucl_num-1`
			`if (btest(i,j)) then`
			`List_all_comb_b2(j+1,i+1) = 1`
			`endif`
			`enddo`
			`enddo`

			`END_PROVIDER`

			`! ---`

			`BEGIN_PROVIDER [ double precision, List_all_comb_b2_coef, ( List_all_comb_b2_size)]`
			`&BEGIN_PROVIDER [ double precision, List_all_comb_b2_expo, ( List_all_comb_b2_size)]`
			`&BEGIN_PROVIDER [ double precision, List_all_comb_b2_cent, (3, List_all_comb_b2_size)]`

			`implicit none`
			`integer :: i, j, k, phase`
			`double precision :: tmp_alphaj, tmp_alphak`
			`double precision :: tmp_cent_x, tmp_cent_y, tmp_cent_z`

			`provide j1b_pen`

			`List_all_comb_b2_coef = 0.d0`
			`List_all_comb_b2_expo = 0.d0`
			`List_all_comb_b2_cent = 0.d0`

			`do i = 1, List_all_comb_b2_size`

			`tmp_cent_x = 0.d0`
			`tmp_cent_y = 0.d0`
			`tmp_cent_z = 0.d0`
			`do j = 1, nucl_num`
			`tmp_alphaj = dble(List_all_comb_b2(j,i)) * j1b_pen(j)`
			`List_all_comb_b2_expo(i) += tmp_alphaj`
			`tmp_cent_x += tmp_alphaj * nucl_coord(j,1)`
			`tmp_cent_y += tmp_alphaj * nucl_coord(j,2)`
			`tmp_cent_z += tmp_alphaj * nucl_coord(j,3)`
			`enddo`

			`if(List_all_comb_b2_expo(i) .lt. 1d-10) cycle`

			`List_all_comb_b2_cent(1,i) = tmp_cent_x / List_all_comb_b2_expo(i)`
			`List_all_comb_b2_cent(2,i) = tmp_cent_y / List_all_comb_b2_expo(i)`
			`List_all_comb_b2_cent(3,i) = tmp_cent_z / List_all_comb_b2_expo(i)`
			`enddo`

			`! ---`

			`do i = 1, List_all_comb_b2_size`

			`do j = 2, nucl_num, 1`
			`tmp_alphaj = dble(List_all_comb_b2(j,i)) * j1b_pen(j)`
			`do k = 1, j-1, 1`
			`tmp_alphak = dble(List_all_comb_b2(k,i)) * j1b_pen(k)`

			`List_all_comb_b2_coef(i) += tmp_alphaj * tmp_alphak * ( (nucl_coord(j,1) - nucl_coord(k,1)) * (nucl_coord(j,1) - nucl_coord(k,1)) &`
			`+ (nucl_coord(j,2) - nucl_coord(k,2)) * (nucl_coord(j,2) - nucl_coord(k,2)) &`
			`+ (nucl_coord(j,3) - nucl_coord(k,3)) * (nucl_coord(j,3) - nucl_coord(k,3)) )`
			`enddo`
			`enddo`

			`if(List_all_comb_b2_expo(i) .lt. 1d-10) cycle`

			`List_all_comb_b2_coef(i) = List_all_comb_b2_coef(i) / List_all_comb_b2_expo(i)`
			`enddo`

			`! ---`

			`do i = 1, List_all_comb_b2_size`

			`phase = 0`
			`do j = 1, nucl_num`
			`phase += List_all_comb_b2(j,i)`
			`enddo`

			`List_all_comb_b2_coef(i) = (-1.d0)*dble(phase) dexp(-List_all_comb_b2_coef(i))`
			`enddo`

remove Gauss_Prod when expo = 0 2023-03-04 14:28:29 +01:00			`!print *, ' coeff, expo & cent of list b2'`
			`!do i = 1, List_all_comb_b2_size`
			`! print*, i, List_all_comb_b2_coef(i), List_all_comb_b2_expo(i)`
			`! print*, List_all_comb_b2_cent(1,i), List_all_comb_b2_cent(2,i), List_all_comb_b2_cent(3,i)`
			`!enddo`
added ao_many_one_e_ints/ bi_ortho_mos/ 2023-02-06 18:17:56 +01:00
			`END_PROVIDER`

			`! ---`

			`BEGIN_PROVIDER [ integer, List_all_comb_b3_size]`

			`implicit none`

			`List_all_comb_b3_size = 3**nucl_num`

			`END_PROVIDER`

			`! ---`

			`BEGIN_PROVIDER [ integer, List_all_comb_b3, (nucl_num, List_all_comb_b3_size)]`

			`implicit none`
			`integer :: i, j, ii, jj`
			`integer, allocatable :: M(:,:), p(:)`

			`if(nucl_num .gt. 32) then`
			`print *, ' nucl_num = ', nucl_num, '> 32'`
			`stop`
			`endif`

			`List_all_comb_b3(:,:) = 0`
			`List_all_comb_b3(:,List_all_comb_b3_size) = 2`

			`allocate(p(nucl_num))`
			`p = 0`

			`do i = 2, List_all_comb_b3_size-1`
			`do j = 1, nucl_num`

			`ii = 0`
			`do jj = 1, j-1, 1`
			`ii = ii + p(jj) * 3**(jj-1)`
			`enddo`
			`p(j) = modulo(i-1-ii, 3j) / 3(j-1)`

			`List_all_comb_b3(j,i) = p(j)`
			`enddo`
			`enddo`

			`END_PROVIDER`

			`! ---`

			`BEGIN_PROVIDER [ double precision, List_all_comb_b3_coef, ( List_all_comb_b3_size)]`
			`&BEGIN_PROVIDER [ double precision, List_all_comb_b3_expo, ( List_all_comb_b3_size)]`
			`&BEGIN_PROVIDER [ double precision, List_all_comb_b3_cent, (3, List_all_comb_b3_size)]`

			`implicit none`
			`integer :: i, j, k, phase`
			`double precision :: tmp_alphaj, tmp_alphak, facto`

			`provide j1b_pen`

			`List_all_comb_b3_coef = 0.d0`
			`List_all_comb_b3_expo = 0.d0`
			`List_all_comb_b3_cent = 0.d0`

			`do i = 1, List_all_comb_b3_size`

			`do j = 1, nucl_num`
			`tmp_alphaj = dble(List_all_comb_b3(j,i)) * j1b_pen(j)`
			`List_all_comb_b3_expo(i) += tmp_alphaj`
			`List_all_comb_b3_cent(1,i) += tmp_alphaj * nucl_coord(j,1)`
			`List_all_comb_b3_cent(2,i) += tmp_alphaj * nucl_coord(j,2)`
			`List_all_comb_b3_cent(3,i) += tmp_alphaj * nucl_coord(j,3)`

			`enddo`

			`if(List_all_comb_b3_expo(i) .lt. 1d-10) cycle`
			`ASSERT(List_all_comb_b3_expo(i) .gt. 0d0)`

			`List_all_comb_b3_cent(1,i) = List_all_comb_b3_cent(1,i) / List_all_comb_b3_expo(i)`
			`List_all_comb_b3_cent(2,i) = List_all_comb_b3_cent(2,i) / List_all_comb_b3_expo(i)`
			`List_all_comb_b3_cent(3,i) = List_all_comb_b3_cent(3,i) / List_all_comb_b3_expo(i)`
			`enddo`

			`! ---`

			`do i = 1, List_all_comb_b3_size`

			`do j = 2, nucl_num, 1`
			`tmp_alphaj = dble(List_all_comb_b3(j,i)) * j1b_pen(j)`
			`do k = 1, j-1, 1`
			`tmp_alphak = dble(List_all_comb_b3(k,i)) * j1b_pen(k)`

			`List_all_comb_b3_coef(i) += tmp_alphaj * tmp_alphak * ( (nucl_coord(j,1) - nucl_coord(k,1)) * (nucl_coord(j,1) - nucl_coord(k,1)) &`
			`+ (nucl_coord(j,2) - nucl_coord(k,2)) * (nucl_coord(j,2) - nucl_coord(k,2)) &`
			`+ (nucl_coord(j,3) - nucl_coord(k,3)) * (nucl_coord(j,3) - nucl_coord(k,3)) )`
			`enddo`
			`enddo`

			`if(List_all_comb_b3_expo(i) .lt. 1d-10) cycle`

			`List_all_comb_b3_coef(i) = List_all_comb_b3_coef(i) / List_all_comb_b3_expo(i)`
			`enddo`

			`! ---`

			`do i = 1, List_all_comb_b3_size`

			`facto = 1.d0`
			`phase = 0`
			`do j = 1, nucl_num`
			`tmp_alphaj = dble(List_all_comb_b3(j,i))`

			`facto = 2.d0 / (gamma(tmp_alphaj+1.d0) gamma(3.d0-tmp_alphaj))`
			`phase += List_all_comb_b3(j,i)`
			`enddo`

			`List_all_comb_b3_coef(i) = (-1.d0)*dble(phase) facto * dexp(-List_all_comb_b3_coef(i))`
			`enddo`

remove Gauss_Prod when expo = 0 2023-03-04 14:28:29 +01:00			`!print *, ' coeff, expo & cent of list b3'`
			`!do i = 1, List_all_comb_b3_size`
			`! print*, i, List_all_comb_b3_coef(i), List_all_comb_b3_expo(i)`
			`! print*, List_all_comb_b3_cent(1,i), List_all_comb_b3_cent(2,i), List_all_comb_b3_cent(3,i)`
			`!enddo`
added ao_many_one_e_ints/ bi_ortho_mos/ 2023-02-06 18:17:56 +01:00
			`END_PROVIDER`

			`! ---`