!!$ !!$ !!$ MLD2P4 version 1.0 !!$ MultiLevel Domain Decomposition Parallel Preconditioners Package !!$ based on PSBLAS (Parallel Sparse BLAS version 2.2) !!$ !!$ (C) Copyright 2008 !!$ !!$ Salvatore Filippone University of Rome Tor Vergata !!$ Alfredo Buttari University of Rome Tor Vergata !!$ Pasqua D'Ambra ICAR-CNR, Naples !!$ Daniela di Serafino Second University of Naples !!$ !!$ 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 MLD2P4 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 MLD2P4 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: mld_cprecinit.f90 ! ! Subroutine: mld_cprecinit ! Version: complex ! ! This routine allocates and initializes the preconditioner data structure, ! according to the preconditioner type chosen by the user. ! ! A default preconditioner is set for each preconditioner type ! specified by the user: ! ! 'NONE', 'NOPREC' - no preconditioner ! ! 'DIAG' - diagonal preconditioner ! ! 'BJAC' - block Jacobi preconditioner, with ILU(0) ! on the local blocks ! ! 'AS' - Restricted Additive Schwarz (RAS), with ! overlap 1 and ILU(0) on the local submatrices ! ! 'ML' - Multilevel hybrid preconditioner (additive on the ! same level and multiplicative through the levels), ! with nlev levels and post-smoothing only. The block ! Jacobi preconditioner, with ILU(0) on the local ! blocks, is applied as post-smoother at each level ! but the coarsest one; four sweeps of the block-Jacobi ! solver, with ILU(0) on the blocks, are applied at ! the coarsest level, on the distributed coarse matrix. ! ! For the multilevel preconditioners, the levels are numbered in increasing ! order starting from the finest one, i.e. level 1 is the finest level. ! ! ! Arguments: ! p - type(mld_cprec_type), input/output. ! The preconditioner data structure. ! ptype - character(len=*), input. ! The type of preconditioner. Its values are 'NONE', ! 'NOPREC', 'DIAG', 'BJAC', 'AS', 'ML' (and the corresponding ! lowercase strings). ! info - integer, output. ! Error code. ! nlev - integer, optional, input. ! The number of levels of the multilevel preconditioner. ! If nlev is not present and ptype='ML', then nlev=2 ! is assumed. If ptype/='ML', nlev is ignored. ! subroutine mld_cprecinit(p,ptype,info,nlev) use psb_base_mod use mld_prec_mod, psb_protect_name => mld_cprecinit implicit none ! Arguments type(mld_cprec_type), intent(inout) :: p character(len=*), intent(in) :: ptype integer, intent(out) :: info integer, optional, intent(in) :: nlev ! Local variables integer :: nlev_, ilev_ character(len=*), parameter :: name='mld_precinit' info = 0 if (allocated(p%baseprecv)) then call mld_precfree(p,info) if (info /=0) then ! Do we want to do something? endif endif select case(psb_toupper(ptype(1:len_trim(ptype)))) case ('NONE','NOPREC') nlev_ = 1 ilev_ = 1 allocate(p%baseprecv(nlev_),stat=info) if (info == 0) call psb_realloc(mld_ifpsz_,p%baseprecv(ilev_)%iprcparm,info) if (info == 0) call psb_realloc(mld_rfpsz_,p%baseprecv(ilev_)%rprcparm,info) if (info /= 0) return p%baseprecv(ilev_)%iprcparm(:) = 0 p%baseprecv(ilev_)%iprcparm(mld_prec_type_) = mld_noprec_ p%baseprecv(ilev_)%iprcparm(mld_sub_solve_) = mld_f_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_restr_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_prol_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_ren_) = 0 p%baseprecv(ilev_)%iprcparm(mld_n_ovr_) = 0 p%baseprecv(ilev_)%iprcparm(mld_smooth_sweeps_) = 1 case ('DIAG') nlev_ = 1 ilev_ = 1 allocate(p%baseprecv(nlev_),stat=info) if (info == 0) call psb_realloc(mld_ifpsz_,p%baseprecv(ilev_)%iprcparm,info) if (info == 0) call psb_realloc(mld_rfpsz_,p%baseprecv(ilev_)%rprcparm,info) if (info /= 0) return p%baseprecv(ilev_)%iprcparm(:) = 0 p%baseprecv(ilev_)%iprcparm(mld_prec_type_) = mld_diag_ p%baseprecv(ilev_)%iprcparm(mld_sub_solve_) = mld_f_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_restr_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_prol_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_ren_) = 0 p%baseprecv(ilev_)%iprcparm(mld_n_ovr_) = 0 p%baseprecv(ilev_)%iprcparm(mld_smooth_sweeps_) = 1 case ('BJAC') nlev_ = 1 ilev_ = 1 allocate(p%baseprecv(nlev_),stat=info) if (info == 0) call psb_realloc(mld_ifpsz_,p%baseprecv(ilev_)%iprcparm,info) if (info == 0) call psb_realloc(mld_rfpsz_,p%baseprecv(ilev_)%rprcparm,info) if (info /= 0) return p%baseprecv(ilev_)%iprcparm(:) = 0 p%baseprecv(ilev_)%iprcparm(mld_prec_type_) = mld_bjac_ p%baseprecv(ilev_)%iprcparm(mld_sub_solve_) = mld_ilu_n_ p%baseprecv(ilev_)%iprcparm(mld_sub_restr_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_prol_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_ren_) = 0 p%baseprecv(ilev_)%iprcparm(mld_n_ovr_) = 0 p%baseprecv(ilev_)%iprcparm(mld_sub_fill_in_) = 0 p%baseprecv(ilev_)%iprcparm(mld_smooth_sweeps_) = 1 case ('AS') nlev_ = 1 ilev_ = 1 allocate(p%baseprecv(nlev_),stat=info) if (info == 0) call psb_realloc(mld_ifpsz_,p%baseprecv(ilev_)%iprcparm,info) if (info == 0) call psb_realloc(mld_rfpsz_,p%baseprecv(ilev_)%rprcparm,info) if (info /= 0) return p%baseprecv(ilev_)%iprcparm(:) = 0 p%baseprecv(ilev_)%iprcparm(mld_prec_type_) = mld_as_ p%baseprecv(ilev_)%iprcparm(mld_sub_solve_) = mld_ilu_n_ p%baseprecv(ilev_)%iprcparm(mld_sub_restr_) = psb_halo_ p%baseprecv(ilev_)%iprcparm(mld_sub_prol_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_ren_) = 0 p%baseprecv(ilev_)%iprcparm(mld_n_ovr_) = 1 p%baseprecv(ilev_)%iprcparm(mld_sub_fill_in_) = 0 p%baseprecv(ilev_)%iprcparm(mld_smooth_sweeps_) = 1 case ('ML') if (present(nlev)) then nlev_ = max(1,nlev) else nlev_ = 2 end if ilev_ = 1 allocate(p%baseprecv(nlev_),stat=info) if (info == 0) call psb_realloc(mld_ifpsz_,p%baseprecv(ilev_)%iprcparm,info) if (info == 0) call psb_realloc(mld_rfpsz_,p%baseprecv(ilev_)%rprcparm,info) if (info /= 0) return p%baseprecv(ilev_)%iprcparm(:) = 0 p%baseprecv(ilev_)%rprcparm(:) = szero p%baseprecv(ilev_)%iprcparm(mld_prec_type_) = mld_as_ p%baseprecv(ilev_)%iprcparm(mld_sub_solve_) = mld_ilu_n_ p%baseprecv(ilev_)%iprcparm(mld_sub_restr_) = psb_halo_ p%baseprecv(ilev_)%iprcparm(mld_sub_prol_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_ren_) = 0 p%baseprecv(ilev_)%iprcparm(mld_n_ovr_) = 0 p%baseprecv(ilev_)%iprcparm(mld_sub_fill_in_) = 0 p%baseprecv(ilev_)%iprcparm(mld_smooth_sweeps_) = 1 if (nlev_ == 1) return do ilev_ = 2, nlev_ -1 if (info == 0) call psb_realloc(mld_ifpsz_,p%baseprecv(ilev_)%iprcparm,info) if (info == 0) call psb_realloc(mld_rfpsz_,p%baseprecv(ilev_)%rprcparm,info) if (info /= 0) return p%baseprecv(ilev_)%iprcparm(:) = 0 p%baseprecv(ilev_)%rprcparm(:) = szero p%baseprecv(ilev_)%iprcparm(mld_prec_type_) = mld_bjac_ p%baseprecv(ilev_)%iprcparm(mld_sub_restr_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_prol_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_ren_) = 0 p%baseprecv(ilev_)%iprcparm(mld_n_ovr_) = 0 p%baseprecv(ilev_)%iprcparm(mld_ml_type_) = mld_mult_ml_ p%baseprecv(ilev_)%iprcparm(mld_aggr_alg_) = mld_dec_aggr_ p%baseprecv(ilev_)%iprcparm(mld_aggr_kind_) = mld_smooth_prol_ p%baseprecv(ilev_)%iprcparm(mld_coarse_mat_) = mld_distr_mat_ p%baseprecv(ilev_)%iprcparm(mld_smooth_pos_) = mld_post_smooth_ p%baseprecv(ilev_)%iprcparm(mld_aggr_eig_) = mld_max_norm_ p%baseprecv(ilev_)%iprcparm(mld_sub_solve_) = mld_ilu_n_ p%baseprecv(ilev_)%iprcparm(mld_sub_fill_in_) = 0 p%baseprecv(ilev_)%iprcparm(mld_smooth_sweeps_) = 1 p%baseprecv(ilev_)%rprcparm(mld_aggr_damp_) = 4.e0/3.e0 end do ilev_ = nlev_ if (info == 0) call psb_realloc(mld_ifpsz_,p%baseprecv(ilev_)%iprcparm,info) if (info == 0) call psb_realloc(mld_rfpsz_,p%baseprecv(ilev_)%rprcparm,info) if (info /= 0) return p%baseprecv(ilev_)%iprcparm(:) = 0 p%baseprecv(ilev_)%rprcparm(:) = szero p%baseprecv(ilev_)%iprcparm(mld_prec_type_) = mld_bjac_ p%baseprecv(ilev_)%iprcparm(mld_sub_restr_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_prol_) = psb_none_ p%baseprecv(ilev_)%iprcparm(mld_sub_ren_) = 0 p%baseprecv(ilev_)%iprcparm(mld_n_ovr_) = 0 p%baseprecv(ilev_)%iprcparm(mld_ml_type_) = mld_mult_ml_ p%baseprecv(ilev_)%iprcparm(mld_aggr_alg_) = mld_dec_aggr_ p%baseprecv(ilev_)%iprcparm(mld_aggr_kind_) = mld_smooth_prol_ p%baseprecv(ilev_)%iprcparm(mld_coarse_mat_) = mld_distr_mat_ p%baseprecv(ilev_)%iprcparm(mld_smooth_pos_) = mld_post_smooth_ p%baseprecv(ilev_)%iprcparm(mld_aggr_eig_) = mld_max_norm_ p%baseprecv(ilev_)%iprcparm(mld_sub_solve_) = mld_ilu_n_ p%baseprecv(ilev_)%iprcparm(mld_sub_fill_in_) = 0 p%baseprecv(ilev_)%iprcparm(mld_smooth_sweeps_) = 4 p%baseprecv(ilev_)%rprcparm(mld_aggr_damp_) = 4.e0/3.e0 case default write(0,*) name,': Warning: Unknown preconditioner type request "',ptype,'"' info = 2 end select end subroutine mld_cprecinit