BEGIN_PROVIDER [ double precision, cholesky_ao_transp, (cholesky_ao_num, ao_num, ao_num) ] implicit none BEGIN_DOC ! Transposed of the Cholesky vectors in AO basis set END_DOC integer :: i,j,k do j=1,ao_num do i=1,ao_num do k=1,ao_num cholesky_ao_transp(k,i,j) = cholesky_ao(i,j,k) enddo enddo enddo END_PROVIDER BEGIN_PROVIDER [ integer, cholesky_ao_num ] &BEGIN_PROVIDER [ double precision, cholesky_ao, (ao_num, ao_num, 1) ] implicit none BEGIN_DOC ! Cholesky vectors in AO basis: (ik|a): ! = (ik|jl) = sum_a (ik|a).(a|jl) ! ! Last dimension of cholesky_ao is cholesky_ao_num END_DOC integer :: rank, ndim double precision :: tau double precision, pointer :: L(:,:), L_old(:,:) double precision :: s double precision, parameter :: dscale = 1.d0 double precision, allocatable :: D(:), Delta(:,:), Ltmp_p(:,:), Ltmp_q(:,:) integer, allocatable :: Lset(:), Dset(:), addr(:,:) logical, allocatable :: computed(:) integer :: i,j,k,m,p,q, qj, dj, p2, q2 integer :: N, np, nq double precision :: Dmax, Dmin, Qmax, f double precision, external :: get_ao_two_e_integral logical, external :: ao_two_e_integral_zero double precision, external :: ao_two_e_integral integer :: block_size, iblock, ierr double precision :: mem double precision, external :: memory_of_double, memory_of_int integer, external :: getUnitAndOpen integer :: iunit ndim = ao_num*ao_num deallocate(cholesky_ao) if (read_ao_cholesky) then print *, 'Reading Cholesky vectors from disk...' iunit = getUnitAndOpen(trim(ezfio_work_dir)//'cholesky_ao', 'R') read(iunit) rank allocate(cholesky_ao(ao_num,ao_num,rank), stat=ierr) read(iunit) cholesky_ao close(iunit) cholesky_ao_num = rank else PROVIDE nucl_coord if (do_direct_integrals) then if (ao_two_e_integral(1,1,1,1) < huge(1.d0)) then ! Trigger providers inside ao_two_e_integral continue endif else PROVIDE ao_two_e_integrals_in_map endif tau = ao_cholesky_threshold mem = 6.d0 * memory_of_double(ndim) + 6.d0 * memory_of_int(ndim) call check_mem(mem, irp_here) call print_memory_usage() allocate(L(ndim,1)) print *, '' print *, 'Cholesky decomposition of AO integrals' print *, '======================================' print *, '' print *, '============ =============' print *, ' Rank Threshold' print *, '============ =============' rank = 0 allocate( D(ndim), Lset(ndim), Dset(ndim) ) allocate( addr(3,ndim) ) ! 1. k=0 do j=1,ao_num do i=1,ao_num k = k+1 addr(1,k) = i addr(2,k) = j addr(3,k) = (i-1)*ao_num + j enddo enddo if (do_direct_integrals) then !$OMP PARALLEL DO DEFAULT(SHARED) PRIVATE(i) SCHEDULE(guided) do i=1,ndim D(i) = ao_two_e_integral(addr(1,i), addr(2,i), & addr(1,i), addr(2,i)) enddo !$OMP END PARALLEL DO else !$OMP PARALLEL DO DEFAULT(SHARED) PRIVATE(i) SCHEDULE(guided) do i=1,ndim D(i) = get_ao_two_e_integral(addr(1,i), addr(1,i), & addr(2,i), addr(2,i), & ao_integrals_map) enddo !$OMP END PARALLEL DO endif Dmax = maxval(D) ! 2. np=0 do p=1,ndim if ( dscale*dscale*Dmax*D(p) > tau*tau ) then np = np+1 Lset(np) = p endif enddo ! 3. N = 0 ! 4. i = 0 ! 5. do while ( (Dmax > tau).and.(rank < ndim) ) ! a. i = i+1 s = 0.01d0 ! Inrease s until the arrays fit in memory do while (.True.) ! b. Dmin = max(s*Dmax,tau) ! c. nq=0 do p=1,np if ( D(Lset(p)) > Dmin ) then nq = nq+1 Dset(nq) = Lset(p) endif enddo call total_memory(mem) mem = mem & + np*memory_of_double(nq) &! Delta(np,nq) + (rank+nq)* memory_of_double(ndim) &! L(ndim,rank+nq) + (np+nq)*memory_of_double(block_size) ! Ltmp_p(np,block_size) + Ltmp_q(nq,block_size) if (mem > qp_max_mem) then s = s*2.d0 else exit endif if ((s > 1.d0).or.(nq == 0)) then call print_memory_usage() print *, 'Not enough memory. Reduce cholesky threshold' stop -1 endif enddo ! d., e. block_size = max(N,24) L_old => L allocate(L(ndim,rank+nq), stat=ierr) if (ierr /= 0) then call print_memory_usage() print *, irp_here, ': allocation failed : (L(ndim,rank+nq))' stop -1 endif !$OMP PARALLEL DO PRIVATE(k,j) do k=1,rank do j=1,ndim L(j,k) = L_old(j,k) enddo enddo !$OMP END PARALLEL DO deallocate(L_old) allocate(Delta(np,nq), stat=ierr) if (ierr /= 0) then call print_memory_usage() print *, irp_here, ': allocation failed : (Delta(np,nq))' stop -1 endif allocate(Ltmp_p(np,block_size), stat=ierr) if (ierr /= 0) then call print_memory_usage() print *, irp_here, ': allocation failed : (Ltmp_p(np,block_size))' stop -1 endif allocate(Ltmp_q(nq,block_size), stat=ierr) if (ierr /= 0) then call print_memory_usage() print *, irp_here, ': allocation failed : (Ltmp_q(nq,block_size))' stop -1 endif allocate(computed(nq)) !$OMP PARALLEL DEFAULT(SHARED) PRIVATE(m,k,p,q,j) !$OMP DO do q=1,nq do j=1,np Delta(j,q) = 0.d0 enddo computed(q) = .False. enddo !$OMP ENDDO NOWAIT !$OMP DO do k=1,N do p=1,np Ltmp_p(p,k) = L(Lset(p),k) enddo do q=1,nq Ltmp_q(q,k) = L(Dset(q),k) enddo enddo !$OMP END DO NOWAIT !$OMP BARRIER !$OMP END PARALLEL if (N>0) then call dgemm('N','T', np, nq, N, -1.d0, & Ltmp_p, np, Ltmp_q, nq, 1.d0, Delta, np) endif ! f. Qmax = D(Dset(1)) do q=1,nq Qmax = max(Qmax, D(Dset(q))) enddo ! g. iblock = 0 do j=1,nq if ( (Qmax <= Dmin).or.(N+j > ndim) ) exit ! i. rank = N+j if (iblock == block_size) then call dgemm('N','T',np,nq,block_size,-1.d0, & Ltmp_p, np, Ltmp_q, nq, 1.d0, Delta, np) iblock = 0 endif ! ii. do dj=1,nq qj = Dset(dj) if (D(qj) == Qmax) then exit endif enddo L(1:ndim, rank) = 0.d0 if (.not.computed(dj)) then m = dj !$OMP PARALLEL DO PRIVATE(k) SCHEDULE(guided) do k=np,1,-1 if (.not.ao_two_e_integral_zero( addr(1,Lset(k)), addr(1,Dset(m)),& addr(2,Lset(k)), addr(2,Dset(m)) ) ) then if (do_direct_integrals) then Delta(k,m) = Delta(k,m) + & ao_two_e_integral(addr(1,Lset(k)), addr(2,Lset(k)),& addr(1,Dset(m)), addr(2,Dset(m))) else Delta(k,m) = Delta(k,m) + & get_ao_two_e_integral( addr(1,Lset(k)), addr(1,Dset(m)),& addr(2,Lset(k)), addr(2,Dset(m)), ao_integrals_map) endif endif enddo !$OMP END PARALLEL DO computed(dj) = .True. endif iblock = iblock+1 do p=1,np Ltmp_p(p,iblock) = Delta(p,dj) enddo ! iv. if (iblock > 1) then call dgemv('N', np, iblock-1, -1.d0, Ltmp_p, np, Ltmp_q(dj,1), nq, 1.d0,& Ltmp_p(1,iblock), 1) endif ! iii. f = 1.d0/dsqrt(Qmax) !$OMP PARALLEL PRIVATE(m,p,q,k) DEFAULT(shared) !$OMP DO do p=1,np Ltmp_p(p,iblock) = Ltmp_p(p,iblock) * f L(Lset(p), rank) = Ltmp_p(p,iblock) D(Lset(p)) = D(Lset(p)) - Ltmp_p(p,iblock) * Ltmp_p(p,iblock) enddo !$OMP END DO !$OMP DO do q=1,nq Ltmp_q(q,iblock) = L(Dset(q), rank) enddo !$OMP END DO !$OMP END PARALLEL Qmax = D(Dset(1)) do q=1,nq Qmax = max(Qmax, D(Dset(q))) enddo enddo print '(I10, 4X, ES12.3)', rank, Qmax deallocate(computed) deallocate(Delta) deallocate(Ltmp_p) deallocate(Ltmp_q) ! i. N = rank ! j. Dmax = D(Lset(1)) do p=1,np Dmax = max(Dmax, D(Lset(p))) enddo np=0 do p=1,ndim if ( dscale*dscale*Dmax*D(p) > tau*tau ) then np = np+1 Lset(np) = p endif enddo enddo allocate(cholesky_ao(ao_num,ao_num,rank), stat=ierr) if (ierr /= 0) then call print_memory_usage() print *, irp_here, ': Allocation failed' stop -1 endif !$OMP PARALLEL DO PRIVATE(k) do k=1,rank call dcopy(ndim, L(1,k), 1, cholesky_ao(1,1,k), 1) enddo !$OMP END PARALLEL DO deallocate(L) cholesky_ao_num = rank print *, '============ =============' print *, '' if (write_ao_cholesky) then print *, 'Writing Cholesky vectors to disk...' iunit = getUnitAndOpen(trim(ezfio_work_dir)//'cholesky_ao', 'W') write(iunit) rank write(iunit) cholesky_ao close(iunit) call ezfio_set_ao_two_e_ints_io_ao_cholesky('Read') endif endif print *, 'Rank : ', cholesky_ao_num, '(', 100.d0*dble(cholesky_ao_num)/dble(ao_num*ao_num), ' %)' print *, '' END_PROVIDER