QuantumPackage/src/ccsd/ccsd_t_space_orb_stoch.irp.f

! Main
subroutine ccsd_par_t_space_stoch(nO,nV,t1,t2,f_o,f_v,v_vvvo,v_vvoo,v_vooo,energy)

  implicit none

  integer, intent(in)           :: nO,nV
  double precision, intent(in)  :: t1(nO,nV), f_o(nO), f_v(nV)
  double precision, intent(in)  :: t2(nO,nO,nV,nV)
  double precision, intent(in)  :: v_vvvo(nV,nV,nV,nO), v_vvoo(nV,nV,nO,nO), v_vooo(nV,nO,nO,nO)
  double precision, intent(inout) :: energy

  double precision, allocatable :: X_vovv(:,:,:,:), X_ooov(:,:,:,:), X_oovv(:,:,:,:)
  double precision, allocatable :: T_voov(:,:,:,:), T_oovv(:,:,:,:)
  integer                       :: i,j,k,l,a,b,c,d
  double precision              :: e,ta,tb,eccsd

  eccsd = energy
  call set_multiple_levels_omp(.False.)

  allocate(X_vovv(nV,nO,nV,nV), X_ooov(nO,nO,nO,nV), X_oovv(nO,nO,nV,nV))
  allocate(T_voov(nV,nO,nO,nV),T_oovv(nO,nO,nV,nV))

  !$OMP PARALLEL &
  !$OMP SHARED(nO,nV,T_voov,T_oovv,X_vovv,X_ooov,X_oovv, &
  !$OMP t1,t2,v_vvvo,v_vooo,v_vvoo) &
  !$OMP PRIVATE(a,b,c,d,i,j,k,l) &
  !$OMP DEFAULT(NONE)

  !v_vvvo(b,a,d,i) * t2(k,j,c,d) &
  !X_vovv(d,i,b,a,i) * T_voov(d,j,c,k)

  !$OMP DO
  do a = 1, nV
    do b = 1, nV
      do i = 1, nO
        do d = 1, nV
          X_vovv(d,i,b,a) = v_vvvo(b,a,d,i)
        enddo
      enddo
    enddo
  enddo
  !$OMP END DO nowait

  !$OMP DO
  do c = 1, nV
    do j = 1, nO
      do k = 1, nO
        do d = 1, nV
          T_voov(d,k,j,c) = t2(k,j,c,d)
        enddo
      enddo
    enddo
  enddo
  !$OMP END DO nowait

  !v_vooo(c,j,k,l) * t2(i,l,a,b) &
  !X_ooov(l,j,k,c) * T_oovv(l,i,a,b) &

  !$OMP DO
  do c = 1, nV
    do k = 1, nO
      do j = 1, nO
        do l = 1, nO
           X_ooov(l,j,k,c) = v_vooo(c,j,k,l)
        enddo
      enddo
    enddo
  enddo
  !$OMP END DO nowait

  !$OMP DO
  do b = 1, nV
    do a = 1, nV
      do i = 1, nO
        do l = 1, nO
          T_oovv(l,i,a,b) = t2(i,l,a,b)
        enddo
      enddo
    enddo
  enddo
  !$OMP END DO nowait

  !X_oovv(j,k,b,c) * T1_vo(a,i) &

  !$OMP DO
  do c = 1, nV
    do b = 1, nV
      do k = 1, nO
        do j = 1, nO
          X_oovv(j,k,b,c) = v_vvoo(b,c,j,k)
        enddo
      enddo
    enddo
  enddo
  !$OMP END DO nowait

  !$OMP END PARALLEL

  double precision, external :: ccsd_t_task_aba
  double precision, external :: ccsd_t_task_abc
!  logical, external :: omp_test_lock

  double precision, allocatable :: memo(:), Pabc(:), waccu(:)
  integer*8, allocatable :: sampled(:)
!  integer(omp_lock_kind), allocatable :: lock(:)
  integer*2       , allocatable :: abc(:,:)
  integer*8                     :: Nabc, i8
  integer*8, allocatable :: iorder(:)
  double precision :: eocc
  double precision :: norm
  integer :: kiter, isample


  ! Prepare table of triplets (a,b,c)

  Nabc = (int(nV,8) * int(nV+1,8) * int(nV+2,8))/6_8 - nV
  allocate (memo(Nabc), sampled(Nabc), Pabc(Nabc), waccu(Nabc))
  allocate (abc(4,Nabc), iorder(Nabc)) !, lock(Nabc))

!  eocc = 3.d0/dble(nO) * sum(f_o(1:nO))
  Nabc = 0_8
  do a = 1, nV
    do b = a+1, nV
      do c = b+1, nV
        Nabc = Nabc + 1_8
        Pabc(Nabc) = -1.d0/(f_v(a) + f_v(b) + f_v(c))
        abc(1,Nabc) = a
        abc(2,Nabc) = b
        abc(3,Nabc) = c
      enddo

      Nabc = Nabc + 1_8
      abc(1,Nabc) = a
      abc(2,Nabc) = b
      abc(3,Nabc) = a
      Pabc(Nabc) = -1.d0/(2.d0*f_v(a) + f_v(b))

      Nabc = Nabc + 1_8
      abc(1,Nabc) = b
      abc(2,Nabc) = a
      abc(3,Nabc) = b
      Pabc(Nabc) = -1.d0/(f_v(a) + 2.d0*f_v(b))
    enddo
  enddo

  do i8=1,Nabc
   iorder(i8) = i8
  enddo

  ! Sort triplets in decreasing Pabc
  call dsort_big(Pabc, iorder, Nabc)

  ! Normalize
  norm = 0.d0
  do i8=Nabc,1,-1
    norm = norm + Pabc(i8)
  enddo
  norm = 1.d0/norm
  do i8=1,Nabc
    Pabc(i8) = Pabc(i8) * norm
  enddo

  call i8set_order_big(abc, iorder, Nabc)


  ! Cumulative distribution for sampling
  waccu(Nabc) = 0.d0
  do i8=Nabc-1,1,-1
   waccu(i8) = waccu(i8+1) - Pabc(i8+1)
  enddo
  waccu(:) = waccu(:) + 1.d0

  logical :: converged, do_comp
  double precision :: eta, variance, error, sample
  double precision :: t00, t01
  integer*8 :: ieta, Ncomputed
  integer*8, external :: binary_search

  integer :: nbuckets
  nbuckets = 100

  double precision, allocatable :: wsum(:)
  allocate(wsum(nbuckets))

  converged = .False.
  Ncomputed = 0_8

  energy = 0.d0
  variance = 0.d0
  memo(:) = 0.d0
  sampled(:) = -1_8

  integer*8 :: ileft, iright, imin
  ileft = 1_8
  iright = Nabc
  integer*8, allocatable :: bounds(:,:)

  allocate (bounds(2,nbuckets))
  do isample=1,nbuckets
    eta = 1.d0/dble(nbuckets) * dble(isample)
    ieta = binary_search(waccu,eta,Nabc,ileft,iright)
    bounds(1,isample) = ileft
    bounds(2,isample) = ieta
    ileft = ieta+1
    wsum(isample) = sum( Pabc(bounds(1,isample):bounds(2,isample) ) )
  enddo

  Pabc(:) = 1.d0/Pabc(:)

  print '(A)', ''
  print '(A)', ' +----------------------+--------------+----------+'
  print '(A)', ' |      E(CCSD(T))      |   Error      |     %    |'
  print '(A)', ' +----------------------+--------------+----------+'


  call wall_time(t00)
  imin = 1_8
  !$OMP PARALLEL                                                     &
      !$OMP PRIVATE(ieta,eta,a,b,c,kiter,isample)                    &
      !$OMP DEFAULT(SHARED)

  do kiter=1,Nabc

    !$OMP MASTER
    do while ((imin <= Nabc).and.(sampled(imin)>-1_8))
      imin = imin+1
    enddo

    ! Deterministic part
    if (imin < Nabc) then
      ieta=imin
      sampled(ieta) = 0_8
      a = abc(1,ieta)
      b = abc(2,ieta)
      c = abc(3,ieta)
      Ncomputed += 1_8
      !$OMP TASK DEFAULT(SHARED) FIRSTPRIVATE(a,b,c,ieta)
      if (a/=c) then
        memo(ieta) = ccsd_t_task_abc(a,b,c,nO,nV,t1,T_oovv,T_voov, &
            X_ooov,X_oovv,X_vovv,f_o,f_v) / 3.d0
      else
        memo(ieta) =  ccsd_t_task_aba(a,b,nO,nV,t1,T_oovv,T_voov,  &
            X_ooov,X_oovv,X_vovv,f_o,f_v) / 3.d0
      endif
      !$OMP END TASK
    endif

    ! Stochastic part
    call random_number(eta)
    do isample=1,nbuckets
      if (imin >= bounds(2,isample)) then
        cycle
      endif
      ieta = binary_search(waccu,(eta + dble(isample-1))/dble(nbuckets),Nabc)

      if (sampled(ieta) == -1_8) then
        sampled(ieta) = 0_8
        a = abc(1,ieta)
        b = abc(2,ieta)
        c = abc(3,ieta)
        Ncomputed += 1_8
        !$OMP TASK DEFAULT(SHARED) FIRSTPRIVATE(a,b,c,ieta)
        if (a/=c) then
          memo(ieta) = ccsd_t_task_abc(a,b,c,nO,nV,t1,T_oovv,T_voov, &
              X_ooov,X_oovv,X_vovv,f_o,f_v) / 3.d0
        else
          memo(ieta) =  ccsd_t_task_aba(a,b,nO,nV,t1,T_oovv,T_voov,  &
              X_ooov,X_oovv,X_vovv,f_o,f_v) / 3.d0
        endif
        !$OMP END TASK
      endif
      sampled(ieta) = sampled(ieta)+1_8

    enddo

    call wall_time(t01)
    if ((t01-t00 > 1.0d0).or.(imin >= Nabc)) then
      t00 = t01

      !$OMP TASKWAIT

      double precision :: ET, ET2
      double precision :: energy_stoch, energy_det
      double precision :: scale
      double precision :: w
      double precision :: tmp
      energy_stoch = 0.d0
      energy_det   = 0.d0
      norm = 0.d0
      scale = 1.d0
      ET = 0.d0
      ET2 = 0.d0


      do isample=1,nbuckets
        if (imin >= bounds(2,isample)) then
          energy_det = energy_det + sum(memo(bounds(1,isample):bounds(2,isample)))
          scale = scale - wsum(isample)
        else
          exit
        endif
      enddo

      do ieta=bounds(1,isample), Nabc
          w = dble(max(sampled(ieta),0_8))
          tmp = w * memo(ieta) * Pabc(ieta)
          ET = ET + tmp
          ET2 = ET2 + tmp * memo(ieta) * Pabc(ieta)
          norm = norm + w
      enddo
      norm = norm/scale
      if (norm > 0.d0) then
        energy_stoch = ET / norm
        variance = ET2 / norm - energy_stoch*energy_stoch
      endif

      energy = energy_det + energy_stoch

      print '('' | '',F20.8, '' | '', E12.4,'' | '', F8.2,'' |'')', eccsd+energy, dsqrt(variance/(norm-1.d0)), 100.*real(Ncomputed)/real(Nabc)
    endif
    !$OMP END MASTER
    if (imin >= Nabc) exit
  enddo

  !$OMP END PARALLEL
  print '(A)', ' +----------------------+--------------+----------+'
  print '(A)', ''

  deallocate(X_vovv,X_ooov,T_voov,T_oovv)
end


integer*8 function binary_search(arr, key, size)
    implicit none
    BEGIN_DOC
! Searches the key in array arr(1:size) between l_in and r_in, and returns its index
    END_DOC
    integer*8 :: size, i, j, mid, l_in, r_in
    double precision, dimension(size) :: arr(1:size)
    double precision :: key

    i = 1_8
    j = size

    do while (j >= i)
        mid = i + (j - i) / 2
        if (arr(mid) >= key) then
            if (mid > 1 .and. arr(mid - 1) < key) then
                binary_search = mid
                return
            end if
            j = mid - 1
        else if (arr(mid) < key) then
            i = mid + 1
        else
            binary_search = mid + 1
            return
        end if
    end do
    binary_search = i
end function binary_search
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`! Main`
			`subroutine ccsd_par_t_space_stoch(nO,nV,t1,t2,f_o,f_v,v_vvvo,v_vvoo,v_vooo,energy)`

			`implicit none`

			`integer, intent(in) :: nO,nV`
			`double precision, intent(in) :: t1(nO,nV), f_o(nO), f_v(nV)`
			`double precision, intent(in) :: t2(nO,nO,nV,nV)`
			`double precision, intent(in) :: v_vvvo(nV,nV,nV,nO), v_vvoo(nV,nV,nO,nO), v_vooo(nV,nO,nO,nO)`
Formatted output in (T) 2023-05-16 19:54:30 +02:00			`double precision, intent(inout) :: energy`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
			`double precision, allocatable :: X_vovv(:,:,:,:), X_ooov(:,:,:,:), X_oovv(:,:,:,:)`
			`double precision, allocatable :: T_voov(:,:,:,:), T_oovv(:,:,:,:)`
			`integer :: i,j,k,l,a,b,c,d`
Formatted output in (T) 2023-05-16 19:54:30 +02:00			`double precision :: e,ta,tb,eccsd`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
Formatted output in (T) 2023-05-16 19:54:30 +02:00			`eccsd = energy`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`call set_multiple_levels_omp(.False.)`

			`allocate(X_vovv(nV,nO,nV,nV), X_ooov(nO,nO,nO,nV), X_oovv(nO,nO,nV,nV))`
			`allocate(T_voov(nV,nO,nO,nV),T_oovv(nO,nO,nV,nV))`

			`!$OMP PARALLEL &`
			`!$OMP SHARED(nO,nV,T_voov,T_oovv,X_vovv,X_ooov,X_oovv, &`
			`!$OMP t1,t2,v_vvvo,v_vooo,v_vvoo) &`
			`!$OMP PRIVATE(a,b,c,d,i,j,k,l) &`
			`!$OMP DEFAULT(NONE)`

			`!v_vvvo(b,a,d,i) * t2(k,j,c,d) &`
			`!X_vovv(d,i,b,a,i) * T_voov(d,j,c,k)`

			`!$OMP DO`
			`do a = 1, nV`
			`do b = 1, nV`
			`do i = 1, nO`
			`do d = 1, nV`
			`X_vovv(d,i,b,a) = v_vvvo(b,a,d,i)`
			`enddo`
			`enddo`
			`enddo`
			`enddo`
			`!$OMP END DO nowait`

			`!$OMP DO`
			`do c = 1, nV`
			`do j = 1, nO`
			`do k = 1, nO`
			`do d = 1, nV`
			`T_voov(d,k,j,c) = t2(k,j,c,d)`
			`enddo`
			`enddo`
			`enddo`
			`enddo`
			`!$OMP END DO nowait`

			`!v_vooo(c,j,k,l) * t2(i,l,a,b) &`
			`!X_ooov(l,j,k,c) * T_oovv(l,i,a,b) &`

			`!$OMP DO`
			`do c = 1, nV`
			`do k = 1, nO`
			`do j = 1, nO`
			`do l = 1, nO`
			`X_ooov(l,j,k,c) = v_vooo(c,j,k,l)`
			`enddo`
			`enddo`
			`enddo`
			`enddo`
			`!$OMP END DO nowait`

			`!$OMP DO`
			`do b = 1, nV`
			`do a = 1, nV`
			`do i = 1, nO`
			`do l = 1, nO`
			`T_oovv(l,i,a,b) = t2(i,l,a,b)`
			`enddo`
			`enddo`
			`enddo`
			`enddo`
			`!$OMP END DO nowait`

			`!X_oovv(j,k,b,c) * T1_vo(a,i) &`

			`!$OMP DO`
			`do c = 1, nV`
			`do b = 1, nV`
			`do k = 1, nO`
			`do j = 1, nO`
			`X_oovv(j,k,b,c) = v_vvoo(b,c,j,k)`
			`enddo`
			`enddo`
			`enddo`
			`enddo`
			`!$OMP END DO nowait`

			`!$OMP END PARALLEL`

			`double precision, external :: ccsd_t_task_aba`
			`double precision, external :: ccsd_t_task_abc`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`! logical, external :: omp_test_lock`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
			`double precision, allocatable :: memo(:), Pabc(:), waccu(:)`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`integer*8, allocatable :: sampled(:)`
			`! integer(omp_lock_kind), allocatable :: lock(:)`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`integer*2 , allocatable :: abc(:,:)`
			`integer*8 :: Nabc, i8`
			`integer*8, allocatable :: iorder(:)`
			`double precision :: eocc`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`double precision :: norm`
			`integer :: kiter, isample`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00

			`! Prepare table of triplets (a,b,c)`

			`Nabc = (int(nV,8) * int(nV+1,8) * int(nV+2,8))/6_8 - nV`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`allocate (memo(Nabc), sampled(Nabc), Pabc(Nabc), waccu(Nabc))`
			`allocate (abc(4,Nabc), iorder(Nabc)) !, lock(Nabc))`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
			`! eocc = 3.d0/dble(nO) * sum(f_o(1:nO))`
			`Nabc = 0_8`
			`do a = 1, nV`
			`do b = a+1, nV`
			`do c = b+1, nV`
			`Nabc = Nabc + 1_8`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`Pabc(Nabc) = -1.d0/(f_v(a) + f_v(b) + f_v(c))`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`abc(1,Nabc) = a`
			`abc(2,Nabc) = b`
			`abc(3,Nabc) = c`
			`enddo`

			`Nabc = Nabc + 1_8`
			`abc(1,Nabc) = a`
			`abc(2,Nabc) = b`
			`abc(3,Nabc) = a`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`Pabc(Nabc) = -1.d0/(2.d0*f_v(a) + f_v(b))`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
			`Nabc = Nabc + 1_8`
			`abc(1,Nabc) = b`
			`abc(2,Nabc) = a`
			`abc(3,Nabc) = b`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`Pabc(Nabc) = -1.d0/(f_v(a) + 2.d0*f_v(b))`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`enddo`
			`enddo`

			`do i8=1,Nabc`
			`iorder(i8) = i8`
			`enddo`

			`! Sort triplets in decreasing Pabc`
			`call dsort_big(Pabc, iorder, Nabc)`

			`! Normalize`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`norm = 0.d0`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`do i8=Nabc,1,-1`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`norm = norm + Pabc(i8)`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`enddo`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`norm = 1.d0/norm`
			`do i8=1,Nabc`
			`Pabc(i8) = Pabc(i8) * norm`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`enddo`

			`call i8set_order_big(abc, iorder, Nabc)`


			`! Cumulative distribution for sampling`
			`waccu(Nabc) = 0.d0`
			`do i8=Nabc-1,1,-1`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`waccu(i8) = waccu(i8+1) - Pabc(i8+1)`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`enddo`
			`waccu(:) = waccu(:) + 1.d0`

Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`logical :: converged, do_comp`
			`double precision :: eta, variance, error, sample`
			`double precision :: t00, t01`
			`integer*8 :: ieta, Ncomputed`
			`integer*8, external :: binary_search`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`integer :: nbuckets`
			`nbuckets = 100`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`double precision, allocatable :: wsum(:)`
			`allocate(wsum(nbuckets))`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
			`converged = .False.`
			`Ncomputed = 0_8`

Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`energy = 0.d0`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`variance = 0.d0`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`memo(:) = 0.d0`
			`sampled(:) = -1_8`

			`integer*8 :: ileft, iright, imin`
			`ileft = 1_8`
			`iright = Nabc`
			`integer*8, allocatable :: bounds(:,:)`

			`allocate (bounds(2,nbuckets))`
			`do isample=1,nbuckets`
			`eta = 1.d0/dble(nbuckets) * dble(isample)`
			`ieta = binary_search(waccu,eta,Nabc,ileft,iright)`
			`bounds(1,isample) = ileft`
			`bounds(2,isample) = ieta`
			`ileft = ieta+1`
			`wsum(isample) = sum( Pabc(bounds(1,isample):bounds(2,isample) ) )`
			`enddo`

			`Pabc(:) = 1.d0/Pabc(:)`

Formatted output in (T) 2023-05-16 19:54:30 +02:00			`print '(A)', ''`
			`print '(A)', ' +----------------------+--------------+----------+'`
			`print '(A)', ' \| E(CCSD(T)) \| Error \| % \|'`
			`print '(A)', ' +----------------------+--------------+----------+'`


Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`call wall_time(t00)`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`imin = 1_8`
			`!$OMP PARALLEL &`
			`!$OMP PRIVATE(ieta,eta,a,b,c,kiter,isample) &`
			`!$OMP DEFAULT(SHARED)`

			`do kiter=1,Nabc`

			`!$OMP MASTER`
			`do while ((imin <= Nabc).and.(sampled(imin)>-1_8))`
			`imin = imin+1`
			`enddo`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`! Deterministic part`
			`if (imin < Nabc) then`
			`ieta=imin`
			`sampled(ieta) = 0_8`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`a = abc(1,ieta)`
			`b = abc(2,ieta)`
			`c = abc(3,ieta)`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`Ncomputed += 1_8`
			`!$OMP TASK DEFAULT(SHARED) FIRSTPRIVATE(a,b,c,ieta)`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`if (a/=c) then`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`memo(ieta) = ccsd_t_task_abc(a,b,c,nO,nV,t1,T_oovv,T_voov, &`
			`X_ooov,X_oovv,X_vovv,f_o,f_v) / 3.d0`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`else`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`memo(ieta) = ccsd_t_task_aba(a,b,nO,nV,t1,T_oovv,T_voov, &`
			`X_ooov,X_oovv,X_vovv,f_o,f_v) / 3.d0`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`endif`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`!$OMP END TASK`
			`endif`

			`! Stochastic part`
			`call random_number(eta)`
			`do isample=1,nbuckets`
			`if (imin >= bounds(2,isample)) then`
			`cycle`
			`endif`
			`ieta = binary_search(waccu,(eta + dble(isample-1))/dble(nbuckets),Nabc)`

			`if (sampled(ieta) == -1_8) then`
			`sampled(ieta) = 0_8`
			`a = abc(1,ieta)`
			`b = abc(2,ieta)`
			`c = abc(3,ieta)`
			`Ncomputed += 1_8`
			`!$OMP TASK DEFAULT(SHARED) FIRSTPRIVATE(a,b,c,ieta)`
			`if (a/=c) then`
			`memo(ieta) = ccsd_t_task_abc(a,b,c,nO,nV,t1,T_oovv,T_voov, &`
			`X_ooov,X_oovv,X_vovv,f_o,f_v) / 3.d0`
			`else`
			`memo(ieta) = ccsd_t_task_aba(a,b,nO,nV,t1,T_oovv,T_voov, &`
			`X_ooov,X_oovv,X_vovv,f_o,f_v) / 3.d0`
			`endif`
			`!$OMP END TASK`
			`endif`
			`sampled(ieta) = sampled(ieta)+1_8`

			`enddo`

			`call wall_time(t01)`
cholesky in big_array 2023-05-17 16:55:29 +02:00			`if ((t01-t00 > 1.0d0).or.(imin >= Nabc)) then`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`t00 = t01`

			`!$OMP TASKWAIT`

			`double precision :: ET, ET2`
			`double precision :: energy_stoch, energy_det`
			`double precision :: scale`
			`double precision :: w`
			`double precision :: tmp`
			`energy_stoch = 0.d0`
			`energy_det = 0.d0`
			`norm = 0.d0`
			`scale = 1.d0`
			`ET = 0.d0`
			`ET2 = 0.d0`


			`do isample=1,nbuckets`
			`if (imin >= bounds(2,isample)) then`
			`energy_det = energy_det + sum(memo(bounds(1,isample):bounds(2,isample)))`
			`scale = scale - wsum(isample)`
			`else`
			`exit`
			`endif`
			`enddo`

			`do ieta=bounds(1,isample), Nabc`
			`w = dble(max(sampled(ieta),0_8))`
			`tmp = w * memo(ieta) * Pabc(ieta)`
			`ET = ET + tmp`
			`ET2 = ET2 + tmp * memo(ieta) * Pabc(ieta)`
			`norm = norm + w`
			`enddo`
			`norm = norm/scale`
			`if (norm > 0.d0) then`
			`energy_stoch = ET / norm`
			`variance = ET2 / norm - energy_stoch*energy_stoch`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`endif`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00
			`energy = energy_det + energy_stoch`

Formatted output in (T) 2023-05-16 19:54:30 +02:00			`print '('' \| '',F20.8, '' \| '', E12.4,'' \| '', F8.2,'' \|'')', eccsd+energy, dsqrt(variance/(norm-1.d0)), 100.*real(Ncomputed)/real(Nabc)`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`endif`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00			`!$OMP END MASTER`
			`if (imin >= Nabc) exit`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00			`enddo`
Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00
			`!$OMP END PARALLEL`
Formatted output in (T) 2023-05-16 19:54:30 +02:00			`print '(A)', ' +----------------------+--------------+----------+'`
			`print '(A)', ''`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00
			`deallocate(X_vovv,X_ooov,T_voov,T_oovv)`
			`end`


Semi-stochastic (T) OK 2023-05-16 18:32:15 +02:00
			`integer*8 function binary_search(arr, key, size)`
			`implicit none`
			`BEGIN_DOC`
			`! Searches the key in array arr(1:size) between l_in and r_in, and returns its index`
			`END_DOC`
			`integer*8 :: size, i, j, mid, l_in, r_in`
			`double precision, dimension(size) :: arr(1:size)`
			`double precision :: key`

			`i = 1_8`
			`j = size`

			`do while (j >= i)`
			`mid = i + (j - i) / 2`
			`if (arr(mid) >= key) then`
			`if (mid > 1 .and. arr(mid - 1) < key) then`
			`binary_search = mid`
			`return`
			`end if`
			`j = mid - 1`
			`else if (arr(mid) < key) then`
			`i = mid + 1`
			`else`
			`binary_search = mid + 1`
			`return`
			`end if`
			`end do`
			`binary_search = i`
			`end function binary_search`
Implementing stochastic (T) 2023-05-16 01:40:40 +02:00