!!$ !!$ Parallel Sparse BLAS v2.0 !!$ (C) Copyright 2006 Salvatore Filippone University of Rome Tor Vergata !!$ Alfredo Buttari University of Rome Tor Vergata !!$ !!$ Redistribution and use in source and binary forms, with or without !!$ modification, are permitted provided that the following conditions !!$ are met: !!$ 1. Redistributions of source code must retain the above copyright !!$ notice, this list of conditions and the following disclaimer. !!$ 2. Redistributions in binary form must reproduce the above copyright !!$ notice, this list of conditions, and the following disclaimer in the !!$ documentation and/or other materials provided with the distribution. !!$ 3. The name of the PSBLAS group or the names of its contributors may !!$ not be used to endorse or promote products derived from this !!$ software without specific written permission. !!$ !!$ THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS !!$ ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED !!$ TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR !!$ PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE PSBLAS GROUP OR ITS CONTRIBUTORS !!$ BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR !!$ CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF !!$ SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS !!$ INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN !!$ CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) !!$ ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE !!$ POSSIBILITY OF SUCH DAMAGE. !!$ !!$ ! File: psb_zcdovr.f90 ! ! Subroutine: psb_zcdovr ! This routine takes a matrix A with its descriptor, and builds the ! auxiliary descriptor corresponding to the number of overlap levels ! specified on input. It really is just a size estimation/allocation ! front end for . ! ! Parameters: ! a - type(). The input sparse matrix. ! desc_a - type(). The input communication descriptor. ! norv - integer. The number of overlap levels. ! desc_ov - type(). The auxiliary output communication descriptor. ! info - integer. Eventually returns an error code. ! Subroutine psb_zcdovr(a,desc_a,novr,desc_ov,info, extype) use psb_tools_mod, psb_protect_name => psb_zcdovr use psb_serial_mod use psb_descriptor_type use psb_error_mod use psb_penv_mod use psb_realloc_mod use psi_mod #ifdef MPI_MOD use mpi #endif Implicit None #ifdef MPI_H include 'mpif.h' #endif ! .. Array Arguments .. integer, intent(in) :: novr Type(psb_zspmat_type), Intent(in) :: a Type(psb_desc_type), Intent(in) :: desc_a Type(psb_desc_type), Intent(inout) :: desc_ov integer, intent(out) :: info integer, intent(in),optional :: extype interface subroutine psb_icdasb(desc_a,info,ext_hv) use psb_descriptor_type Type(psb_desc_type), intent(inout) :: desc_a integer, intent(out) :: info logical, intent(in),optional :: ext_hv end subroutine psb_icdasb end interface integer icomm, err_act ! .. Local Scalars .. Integer :: i, j, k, np, me,m,nnzero,& & ictxt, lovr, lworks,lworkr, n_row,n_col, int_err(5),& & index_dim,elem_dim, l_tmp_ovr_idx,l_tmp_halo, nztot,nhalo Integer :: counter,counter_h, counter_o, counter_e,idx,gidx,proc,n_elem_recv,& & n_elem_send,tot_recv,tot_elem,cntov_o,& & counter_t,n_elem,i_ovr,jj,proc_id,isz, mglob, glx, & & idxr, idxs, lx, iszr, iszs, nxch, nsnd, nrcv,lidx,irsv, extype_ type(psb_zspmat_type) :: blk Integer, allocatable :: tmp_halo(:),tmp_ovr_idx(:), orig_ovr(:) Integer,allocatable :: halo(:),works(:),workr(:),t_halo_in(:),& & t_halo_out(:),temp(:),maskr(:) Integer,allocatable :: brvindx(:),rvsz(:), bsdindx(:),sdsz(:) Logical,Parameter :: debug=.false. character(len=20) :: name, ch_err name='psb_cdovr' info = 0 call psb_erractionsave(err_act) ictxt=psb_cd_get_context(desc_a) Call psb_info(ictxt, me, np) If(debug) Write(0,*)'in psb_cdovr',novr if (present(extype)) then extype_ = extype else extype_ = psb_ovt_xhal_ endif m = psb_cd_get_local_rows(desc_a) nnzero = Size(a%aspk) n_row = psb_cd_get_local_rows(desc_a) n_col = psb_cd_get_local_cols(desc_a) nhalo = n_col-m If(debug) Write(0,*)'IN CDOVR1',novr ,m,nnzero,n_col if (novr<0) then info=10 int_err(1)=1 int_err(2)=novr call psb_errpush(info,name,i_err=int_err) goto 9999 endif if (debug) write(0,*) 'Calling desccpy' call psb_cdcpy(desc_a,desc_ov,info) if (info /= 0) then info=4010 ch_err='psb_cdcpy' call psb_errpush(info,name,a_err=ch_err) goto 9999 end if if (debug) write(0,*) 'From desccpy' if (novr==0) then ! ! Just copy the input. ! return endif call psb_get_mpicomm(ictxt,icomm ) If(debug)then Write(0,*)'BEGIN cdovr',me,nhalo call psb_barrier(ictxt) endif ! ! Ok, since we are only estimating, do it as follows: ! LOVR= (NNZ/NROW)*N_HALO*NOVR This assumes that the local average ! nonzeros per row is the same as the global. ! nztot = psb_sp_get_nnzeros(a) if (nztot>0) then lovr = ((nztot+m-1)/m)*nhalo*novr lworks = ((nztot+m-1)/m)*nhalo lworkr = ((nztot+m-1)/m)*nhalo else info=-1 call psb_errpush(info,name) goto 9999 endif If(debug)Write(0,*)'ovr_est done',me,novr,lovr index_dim = size(desc_a%halo_index) elem_dim = size(desc_a%halo_index) l_tmp_ovr_idx = novr*(3*Max(2*index_dim,1)+1) l_tmp_halo = novr*(3*Size(desc_a%halo_index)) !!$ write(0,*) 'Size of desc_ov ', desc_ov%matrix_data(psb_desc_size_), & !!$ & psb_desc_normal_,psb_desc_large_ call psb_cd_set_bld(desc_ov,info) If(debug) then Write(0,*)'Start cdovrbld',me,lworks,lworkr call psb_barrier(ictxt) endif Allocate(brvindx(np+1),rvsz(np),sdsz(np),bsdindx(np+1),stat=info) if (info /= 0) then call psb_errpush(4010,name,a_err='Allocate') goto 9999 end if Allocate(works(lworks),workr(lworkr),t_halo_in(l_tmp_halo),& & t_halo_out(l_tmp_halo), temp(lworkr),stat=info) if (info /= 0) then call psb_errpush(4010,name,a_err='Allocate') goto 9999 end if call psb_sp_all(blk,max(lworks,lworkr),info) if (info /= 0) then info=4010 ch_err='psb_sp_all' call psb_errpush(info,name,a_err=ch_err) goto 9999 end if blk%fida='COO' Allocate(orig_ovr(l_tmp_ovr_idx),tmp_ovr_idx(l_tmp_ovr_idx),& & tmp_halo(l_tmp_halo), halo(size(desc_a%halo_index)),stat=info) if (info /= 0) then call psb_errpush(4010,name,a_err='Allocate') goto 9999 end if halo(:) = desc_a%halo_index(:) desc_ov%ovrlap_elem(:) = -1 tmp_ovr_idx(:) = -1 orig_ovr(:) = -1 tmp_halo(:) = -1 counter_e = 1 tot_recv = 0 counter_h = 1 counter_o = 1 cntov_o = 1 ! Init overlap with desc_a%ovrlap (if any) counter = 1 Do While (desc_a%ovrlap_index(counter) /= -1) proc = desc_a%ovrlap_index(counter+psb_proc_id_) n_elem_recv = desc_a%ovrlap_index(counter+psb_n_elem_recv_) n_elem_send = desc_a%ovrlap_index(counter+n_elem_recv+psb_n_elem_send_) Do j=0,n_elem_recv-1 idx = desc_a%ovrlap_index(counter+psb_elem_recv_+j) If(idx > Size(desc_ov%loc_to_glob)) then info=-3 call psb_errpush(info,name) goto 9999 endif gidx = desc_ov%loc_to_glob(idx) call psb_ensure_size((cntov_o+3),orig_ovr,info,pad=-1) if (info /= 0) then info=4010 call psb_errpush(info,name,a_err='psb_ensure_size') goto 9999 end if orig_ovr(cntov_o)=proc orig_ovr(cntov_o+1)=1 orig_ovr(cntov_o+2)=gidx orig_ovr(cntov_o+3)=-1 cntov_o=cntov_o+3 end Do counter=counter+n_elem_recv+n_elem_send+2 end Do ! ! A picture is in order to understand what goes on here. ! I is the internal part; H is halo, R row, C column. The final ! matrix with N levels of overlap looks like this ! ! I | Hc1 | 0 | 0 | ! -------|-----|-----|-----| ! Hr1 | Hd1 | Hc2 | 0 | ! -------|-----|-----|-----| ! 0 | Hr2 | Hd2 | Hc2 | ! -------|-----|-----|-----| ! 0 | 0 | Hr3 | Hd3 | Hc3 ! ! At the start we already have I and Hc1, so we know the row ! indices that will make up Hr1, and also who owns them. As we ! actually get those rows, we receive the column indices in Hc2; ! these define the row indices for Hr2, and so on. When we have ! reached the desired level HrN. ! ! Do i_ovr = 1, novr if (debug) write(0,*) me,'Running on overlap level ',i_ovr,' of ',novr ! ! At this point, halo contains a valid halo corresponding to the ! matrix enlarged with the elements in the frontier for I_OVR-1. ! At the start, this is just the halo for A; the rows for indices in ! the first halo will contain column indices defining the second halo ! level and so on. ! bsdindx(:) = 0 sdsz(:) = 0 brvindx(:) = 0 rvsz(:) = 0 idxr = 0 idxs = 0 counter = 1 counter_t = 1 desc_ov%matrix_data(psb_n_row_)=desc_ov%matrix_data(psb_n_col_) Do While (halo(counter) /= -1) tot_elem=0 proc=halo(counter+psb_proc_id_) n_elem_recv=halo(counter+psb_n_elem_recv_) n_elem_send=halo(counter+n_elem_recv+psb_n_elem_send_) If ((counter+n_elem_recv+n_elem_send) > Size(halo)) then info = -1 call psb_errpush(info,name) goto 9999 end If tot_recv=tot_recv+n_elem_recv if (debug) write(0,*) me,' CDOVRBLD tot_recv:',proc,n_elem_recv,tot_recv ! ! ! The format of the halo vector exists in two forms: 1. Temporary ! 2. Assembled. In this loop we are using the (assembled) halo_in and ! copying it into (temporary) halo_out; this is because tmp_halo will ! be enlarged with the new column indices received, and will reassemble ! everything for the next iteration. ! ! ! add recv elements in halo_index into ovrlap_index ! Do j=0,n_elem_recv-1 If((counter+psb_elem_recv_+j)>Size(halo)) then info=-2 call psb_errpush(info,name) goto 9999 end If idx = halo(counter+psb_elem_recv_+j) If(idx > Size(desc_ov%loc_to_glob)) then info=-3 call psb_errpush(info,name) goto 9999 endif gidx = desc_ov%loc_to_glob(idx) call psb_ensure_size((counter_o+3),tmp_ovr_idx,info,pad=-1) if (info /= 0) then info=4010 call psb_errpush(info,name,a_err='psb_ensure_size') goto 9999 end if tmp_ovr_idx(counter_o)=proc tmp_ovr_idx(counter_o+1)=1 tmp_ovr_idx(counter_o+2)=gidx tmp_ovr_idx(counter_o+3)=-1 counter_o=counter_o+3 call psb_ensure_size((counter_h+3),tmp_halo,info,pad=-1) if (info /= 0) then info=4010 call psb_errpush(info,name,a_err='psb_ensure_size') goto 9999 end if tmp_halo(counter_h)=proc tmp_halo(counter_h+1)=1 tmp_halo(counter_h+2)=idx tmp_halo(counter_h+3)=-1 counter_h=counter_h+3 Enddo if (debug) write(0,*) me,'Checktmp_o_i Loop Mid1',tmp_ovr_idx(1:10) counter = counter+n_elem_recv ! ! add send elements in halo_index into ovrlap_index ! Do j=0,n_elem_send-1 idx = halo(counter+psb_elem_send_+j) gidx = desc_ov%loc_to_glob(idx) if (idx > psb_cd_get_local_rows(Desc_a)) & & write(0,*) me,i_ovr,'Out of local rows ',& & idx,psb_cd_get_local_rows(Desc_a) call psb_ensure_size((counter_o+3),tmp_ovr_idx,info,pad=-1) if (info /= 0) then info=4010 call psb_errpush(info,name,a_err='psb_ensure_size') goto 9999 end if tmp_ovr_idx(counter_o)=proc tmp_ovr_idx(counter_o+1)=1 tmp_ovr_idx(counter_o+2)=gidx tmp_ovr_idx(counter_o+3)=-1 counter_o=counter_o+3 ! ! Prepare to exchange the halo rows with the other proc. ! If (i_ovr <= (novr)) Then n_elem = psb_sp_get_nnz_row(idx,a) call psb_ensure_size((idxs+tot_elem+n_elem),works,info) if (info /= 0) then info=4010 call psb_errpush(info,name,a_err='psb_ensure_size') goto 9999 end if If((n_elem) > size(blk%ia2)) Then isz = max((3*size(blk%ia2))/2,(n_elem)) if (debug) write(0,*) me,'Realloc blk',isz call psb_sp_reall(blk,isz,info) if (info /= 0) then info=4010 ch_err='psb_sp_reall' call psb_errpush(info,name,a_err=ch_err) goto 9999 end if End If call psb_sp_getblk(idx,a,blk,info) if (info /= 0) then info=4010 ch_err='psb_sp_getblk' call psb_errpush(info,name,a_err=ch_err) goto 9999 end if !!$ write(0,*) me,'Iteration: ',j,i_ovr Do jj=1,n_elem works(idxs+tot_elem+jj)=desc_ov%loc_to_glob(blk%ia2(jj)) End Do tot_elem=tot_elem+n_elem End If Enddo if (i_ovr <= novr) then if (tot_elem > 1) then call psb_msort(works(idxs+1:idxs+tot_elem)) lx = works(idxs+1) i = 1 j = 1 do j = j + 1 if (j > tot_elem) exit if (works(idxs+j) /= lx) then i = i + 1 works(idxs+i) = works(idxs+j) lx = works(idxs+i) end if end do tot_elem = i endif if (debug) write(0,*) me,'Checktmp_o_i Loop Mid2',tmp_ovr_idx(1:10) sdsz(proc+1) = tot_elem idxs = idxs + tot_elem end if counter = counter+n_elem_send+3 if (debug) write(0,*) me,'Checktmp_o_i Loop End',tmp_ovr_idx(1:10) Enddo if (debug) write(0,*)me,'End phase 1 CDOVRBLD', m, n_col, tot_recv if (i_ovr <= novr) then ! ! Exchange data requests with everybody else: so far we have ! accumulated RECV requests, we have an all-to-all to build ! matchings SENDs. ! call mpi_alltoall(sdsz,1,mpi_integer,rvsz,1,mpi_integer,icomm,info) if (info /= 0) then info=4010 ch_err='mpi_alltoall' call psb_errpush(info,name,a_err=ch_err) goto 9999 end if idxs = 0 idxr = 0 counter = 1 Do proc=halo(counter) if (proc == -1) exit n_elem_recv = halo(counter+psb_n_elem_recv_) counter = counter+n_elem_recv n_elem_send = halo(counter+psb_n_elem_send_) bsdindx(proc+1) = idxs idxs = idxs + sdsz(proc+1) brvindx(proc+1) = idxr idxr = idxr + rvsz(proc+1) counter = counter+n_elem_send+3 Enddo iszr=sum(rvsz) if (max(iszr,1) > lworkr) then call psb_realloc(max(iszr,1),workr,info) if (info /= 0) then info=4010 ch_err='psb_realloc' call psb_errpush(info,name,a_err=ch_err) goto 9999 end if lworkr=max(iszr,1) end if call mpi_alltoallv(works,sdsz,bsdindx,mpi_integer,& & workr,rvsz,brvindx,mpi_integer,icomm,info) if (info /= 0) then info=4010 ch_err='mpi_alltoallv' call psb_errpush(info,name,a_err=ch_err) goto 9999 end if if (debug) write(0,*) 'ISZR :',iszr if (psb_is_large_desc(desc_ov)) then call psb_ensure_size(iszr,maskr,info) if (info /= 0) then info=4010 call psb_errpush(info,name,a_err='psb_ensure_size') goto 9999 end if call psi_idx_cnv(iszr,workr,maskr,desc_ov,info) iszs = count(maskr(1:iszr)<=0) if (iszs > size(works)) call psb_realloc(iszs,works,info) j = 0 do i=1,iszr if (maskr(i) < 0) then j=j+1 works(j) = workr(i) end if end do ! ! fnd_owner on desc_a because we want the procs who ! owned the rows from the beginning! ! call psi_fnd_owner(iszs,works,temp,desc_a,info) n_col=psb_cd_get_local_cols(desc_ov) do i=1,iszs idx = works(i) n_col = psb_cd_get_local_cols(desc_ov) call psi_idx_ins_cnv(idx,lidx,desc_ov,info) if (psb_cd_get_local_cols(desc_ov) > n_col ) then ! ! This is a new index. Assigning a local index as ! we receive them guarantees that all indices for HALO(I) ! will be less than those for HALO(J) whenever I ovrlap ! 2. (tmp_halo + t_halo_in) -> halo ! 3. (t_ovr_idx) -> /dev/null ! 4. n_row(ov) = n_row(a) ! 5. n_col(ov) current. ! desc_ov%matrix_data(psb_n_row_) = desc_a%matrix_data(psb_n_row_) call psb_transfer(orig_ovr,desc_ov%ovrlap_index,info) call psb_ensure_size((counter_h+counter_t+1),tmp_halo,info,pad=-1) if (info /= 0) then call psb_errpush(4010,name,a_err='psb_ensure_size') goto 9999 end if tmp_halo(counter_h:counter_h+counter_t-1) = t_halo_in(1:counter_t) counter_h = counter_h+counter_t-1 tmp_halo(counter_h:) = -1 call psb_transfer(tmp_halo,desc_ov%halo_index,info) deallocate(tmp_ovr_idx,stat=info) if (info /= 0) then call psb_errpush(4010,name,a_err='deallocate') goto 9999 end if case(psb_ovt_asov_) ! ! Build an overlapped descriptor for Additive Schwarz ! with overlap enlargement; we need the overlap, ! the (new) halo and the mapping into the new index space. ! Here we need: 1. (orig_ovr + t_ovr_idx -> ovrlap ! 2. (tmp_halo) -> ext ! 3. (t_halo_in) -> halo ! 4. n_row(ov) current. ! 5. n_col(ov) current. ! call psb_ensure_size((cntov_o+counter_o+1),orig_ovr,info,pad=-1) if (info /= 0) then call psb_errpush(4010,name,a_err='psb_ensure_size') goto 9999 end if orig_ovr(cntov_o:cntov_o+counter_o-1) = tmp_ovr_idx(1:counter_o) cntov_o = cntov_o+counter_o-1 orig_ovr(cntov_o:) = -1 call psb_transfer(orig_ovr,desc_ov%ovrlap_index,info) deallocate(tmp_ovr_idx,stat=info) if (info /= 0) then call psb_errpush(4010,name,a_err='deallocate') goto 9999 end if tmp_halo(counter_h:) = -1 call psb_transfer(tmp_halo,desc_ov%ext_index,info) call psb_transfer(t_halo_in,desc_ov%halo_index,info) case default call psb_errpush(30,name,i_err=(/5,extype_,0,0,0/)) goto 9999 end select ! ! At this point we have gathered all the indices in the halo at ! N levels of overlap. Just call icdasb forcing to use ! the halo_index provided. This is the same routine as gets ! called inside CDASB. ! if (debug) then write(0,*) 'psb_cdovrbld: converting indexes' call psb_barrier(ictxt) end if call psb_icdasb(desc_ov,info,ext_hv=.true.) if (debug) then write(0,*) me,'Done CDASB' call psb_barrier(ictxt) end if if (info == 0) call psb_sp_free(blk,info) if (info /= 0) then ch_err='sp_free' call psb_errpush(4013,name,a_err=ch_err,i_err=(/info,0,0,0,0/)) goto 9999 end if call psb_erractionrestore(err_act) return 9999 continue call psb_erractionrestore(err_act) if (err_act == psb_act_abort_) then call psb_error(ictxt) return end if Return End Subroutine psb_zcdovr