#define PETSCMAT_DLL /* Provides an interface to the MUMPS sparse solver */ #include "../src/mat/impls/aij/seq/aij.h" #include "../src/mat/impls/aij/mpi/mpiaij.h" #include "../src/mat/impls/sbaij/seq/sbaij.h" #include "../src/mat/impls/sbaij/mpi/mpisbaij.h" EXTERN_C_BEGIN #if defined(PETSC_USE_COMPLEX) #include "zmumps_c.h" #else #include "dmumps_c.h" #endif EXTERN_C_END #define JOB_INIT -1 #define JOB_END -2 /* macros s.t. indices match MUMPS documentation */ #define ICNTL(I) icntl[(I)-1] #define CNTL(I) cntl[(I)-1] #define INFOG(I) infog[(I)-1] #define INFO(I) info[(I)-1] #define RINFOG(I) rinfog[(I)-1] #define RINFO(I) rinfo[(I)-1] typedef struct { #if defined(PETSC_USE_COMPLEX) ZMUMPS_STRUC_C id; #else DMUMPS_STRUC_C id; #endif MatStructure matstruc; PetscMPIInt myid,size; PetscInt *irn,*jcn,sym,nSolve; PetscScalar *val; MPI_Comm comm_mumps; VecScatter scat_rhs, scat_sol; PetscTruth isAIJ,CleanUpMUMPS; Vec b_seq,x_seq; PetscErrorCode (*MatDestroy)(Mat); } Mat_MUMPS; EXTERN PetscErrorCode MatDuplicate_MUMPS(Mat,MatDuplicateOption,Mat*); /* convert Petsc mpiaij matrix to triples: row[nz], col[nz], val[nz] */ /* input: A - matrix in mpiaij or mpisbaij (bs=1) format shift - 0: C style output triple; 1: Fortran style output triple. valOnly - FALSE: spaces are allocated and values are set for the triple TRUE: only the values in v array are updated output: nnz - dim of r, c, and v (number of local nonzero entries of A) r, c, v - row and col index, matrix values (matrix triples) */ PetscErrorCode MatConvertToTriples(Mat A,int shift,PetscTruth valOnly,int *nnz,int **r, int **c, PetscScalar **v) { PetscInt *ai, *aj, *bi, *bj, rstart,nz, *garray; PetscErrorCode ierr; PetscInt i,j,jj,jB,irow,m=A->rmap->n,*ajj,*bjj,countA,countB,colA_start,jcol; PetscInt *row,*col; PetscScalar *av, *bv,*val; PetscTruth isAIJ; PetscFunctionBegin; ierr = PetscTypeCompare((PetscObject)A,MATMPIAIJ,&isAIJ);CHKERRQ(ierr); if (isAIJ){ Mat_MPIAIJ *mat = (Mat_MPIAIJ*)A->data; Mat_SeqAIJ *aa=(Mat_SeqAIJ*)(mat->A)->data; Mat_SeqAIJ *bb=(Mat_SeqAIJ*)(mat->B)->data; nz = aa->nz + bb->nz; ai=aa->i; aj=aa->j; bi=bb->i; bj=bb->j; rstart= A->rmap->rstart; garray = mat->garray; av=aa->a; bv=bb->a; } else { Mat_MPISBAIJ *mat = (Mat_MPISBAIJ*)A->data; Mat_SeqSBAIJ *aa=(Mat_SeqSBAIJ*)(mat->A)->data; Mat_SeqBAIJ *bb=(Mat_SeqBAIJ*)(mat->B)->data; if (A->rmap->bs > 1) SETERRQ1(PETSC_ERR_SUP," bs=%d is not supported yet\n", A->rmap->bs); nz = aa->nz + bb->nz; ai=aa->i; aj=aa->j; bi=bb->i; bj=bb->j; rstart= A->rmap->rstart; garray = mat->garray; av=aa->a; bv=bb->a; } if (!valOnly){ ierr = PetscMalloc(nz*sizeof(PetscInt) ,&row);CHKERRQ(ierr); ierr = PetscMalloc(nz*sizeof(PetscInt),&col);CHKERRQ(ierr); ierr = PetscMalloc(nz*sizeof(PetscScalar),&val);CHKERRQ(ierr); *r = row; *c = col; *v = val; } else { row = *r; col = *c; val = *v; } *nnz = nz; jj = 0; irow = rstart; for ( i=0; ispptr; PetscErrorCode ierr; PetscMPIInt size=lu->size; PetscFunctionBegin; if (lu->CleanUpMUMPS) { /* Terminate instance, deallocate memories */ if (size > 1){ ierr = PetscFree(lu->id.sol_loc);CHKERRQ(ierr); ierr = VecScatterDestroy(lu->scat_rhs);CHKERRQ(ierr); ierr = VecDestroy(lu->b_seq);CHKERRQ(ierr); if (lu->nSolve && lu->scat_sol){ierr = VecScatterDestroy(lu->scat_sol);CHKERRQ(ierr);} if (lu->nSolve && lu->x_seq){ierr = VecDestroy(lu->x_seq);CHKERRQ(ierr);} ierr = PetscFree(lu->val);CHKERRQ(ierr); } lu->id.job=JOB_END; #if defined(PETSC_USE_COMPLEX) zmumps_c(&lu->id); #else dmumps_c(&lu->id); #endif ierr = PetscFree(lu->irn);CHKERRQ(ierr); ierr = PetscFree(lu->jcn);CHKERRQ(ierr); ierr = MPI_Comm_free(&(lu->comm_mumps));CHKERRQ(ierr); } ierr = (lu->MatDestroy)(A);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatSolve_MUMPS" PetscErrorCode MatSolve_MUMPS(Mat A,Vec b,Vec x) { Mat_MUMPS *lu=(Mat_MUMPS*)A->spptr; PetscScalar *array; Vec x_seq; IS is_iden,is_petsc; PetscErrorCode ierr; PetscInt i; PetscFunctionBegin; lu->id.nrhs = 1; x_seq = lu->b_seq; if (lu->size > 1){ /* MUMPS only supports centralized rhs. Scatter b into a seqential rhs vector */ ierr = VecScatterBegin(lu->scat_rhs,b,x_seq,INSERT_VALUES,SCATTER_FORWARD);CHKERRQ(ierr); ierr = VecScatterEnd(lu->scat_rhs,b,x_seq,INSERT_VALUES,SCATTER_FORWARD);CHKERRQ(ierr); if (!lu->myid) {ierr = VecGetArray(x_seq,&array);CHKERRQ(ierr);} } else { /* size == 1 */ ierr = VecCopy(b,x);CHKERRQ(ierr); ierr = VecGetArray(x,&array);CHKERRQ(ierr); } if (!lu->myid) { /* define rhs on the host */ #if defined(PETSC_USE_COMPLEX) lu->id.rhs = (mumps_double_complex*)array; #else lu->id.rhs = array; #endif } if (lu->size == 1){ ierr = VecRestoreArray(x,&array);CHKERRQ(ierr); } else if (!lu->myid){ ierr = VecRestoreArray(x_seq,&array);CHKERRQ(ierr); } if (lu->size > 1){ /* distributed solution */ lu->id.ICNTL(21) = 1; if (!lu->nSolve){ /* Create x_seq=sol_loc for repeated use */ PetscInt lsol_loc; PetscScalar *sol_loc; lsol_loc = lu->id.INFO(23); /* length of sol_loc */ ierr = PetscMalloc((1+lsol_loc)*(sizeof(PetscScalar)+sizeof(PetscInt)),&sol_loc);CHKERRQ(ierr); lu->id.isol_loc = (PetscInt *)(sol_loc + lsol_loc); lu->id.lsol_loc = lsol_loc; #if defined(PETSC_USE_COMPLEX) lu->id.sol_loc = (mumps_double_complex*)sol_loc; #else lu->id.sol_loc = sol_loc; #endif ierr = VecCreateSeqWithArray(PETSC_COMM_SELF,lsol_loc,sol_loc,&lu->x_seq);CHKERRQ(ierr); } } /* solve phase */ /*-------------*/ lu->id.job = 3; #if defined(PETSC_USE_COMPLEX) zmumps_c(&lu->id); #else dmumps_c(&lu->id); #endif if (lu->id.INFOG(1) < 0) { SETERRQ1(PETSC_ERR_LIB,"Error reported by MUMPS in solve phase: INFOG(1)=%d\n",lu->id.INFOG(1)); } if (lu->size > 1) { /* convert mumps distributed solution to petsc mpi x */ if (!lu->nSolve){ /* create scatter scat_sol */ ierr = ISCreateStride(PETSC_COMM_SELF,lu->id.lsol_loc,0,1,&is_iden);CHKERRQ(ierr); /* from */ for (i=0; iid.lsol_loc; i++){ lu->id.isol_loc[i] -= 1; /* change Fortran style to C style */ } ierr = ISCreateGeneral(PETSC_COMM_SELF,lu->id.lsol_loc,lu->id.isol_loc,&is_petsc);CHKERRQ(ierr); /* to */ ierr = VecScatterCreate(lu->x_seq,is_iden,x,is_petsc,&lu->scat_sol);CHKERRQ(ierr); ierr = ISDestroy(is_iden);CHKERRQ(ierr); ierr = ISDestroy(is_petsc);CHKERRQ(ierr); } ierr = VecScatterBegin(lu->scat_sol,lu->x_seq,x,INSERT_VALUES,SCATTER_FORWARD);CHKERRQ(ierr); ierr = VecScatterEnd(lu->scat_sol,lu->x_seq,x,INSERT_VALUES,SCATTER_FORWARD);CHKERRQ(ierr); } lu->nSolve++; PetscFunctionReturn(0); } #if !defined(PETSC_USE_COMPLEX) /* input: F: numeric factor output: nneg: total number of negative pivots nzero: 0 npos: (global dimension of F) - nneg */ #undef __FUNCT__ #define __FUNCT__ "MatGetInertia_SBAIJMUMPS" PetscErrorCode MatGetInertia_SBAIJMUMPS(Mat F,int *nneg,int *nzero,int *npos) { Mat_MUMPS *lu =(Mat_MUMPS*)F->spptr; PetscErrorCode ierr; PetscMPIInt size; PetscFunctionBegin; ierr = MPI_Comm_size(((PetscObject)F)->comm,&size);CHKERRQ(ierr); /* MUMPS 4.3.1 calls ScaLAPACK when ICNTL(13)=0 (default), which does not offer the possibility to compute the inertia of a dense matrix. Set ICNTL(13)=1 to skip ScaLAPACK */ if (size > 1 && lu->id.ICNTL(13) != 1){ SETERRQ1(PETSC_ERR_ARG_WRONG,"ICNTL(13)=%d. -mat_mumps_icntl_13 must be set as 1 for correct global matrix inertia\n",lu->id.INFOG(13)); } if (nneg){ if (!lu->myid){ *nneg = lu->id.INFOG(12); } ierr = MPI_Bcast(nneg,1,MPI_INT,0,lu->comm_mumps);CHKERRQ(ierr); } if (nzero) *nzero = 0; if (npos) *npos = F->rmap->N - (*nneg); PetscFunctionReturn(0); } #endif /* !defined(PETSC_USE_COMPLEX) */ #undef __FUNCT__ #define __FUNCT__ "MatFactorNumeric_MUMPS" PetscErrorCode MatFactorNumeric_MUMPS(Mat F,Mat A,const MatFactorInfo *info) { Mat_MUMPS *lu =(Mat_MUMPS*)(F)->spptr; PetscErrorCode ierr; PetscInt rnz,nnz,nz=0,i,M=A->rmap->N,*ai,*aj,icntl; PetscTruth valOnly,flg; Mat F_diag; IS is_iden; Vec b; PetscTruth isSeqAIJ,isSeqSBAIJ; PetscFunctionBegin; ierr = PetscTypeCompare((PetscObject)A,MATSEQAIJ,&isSeqAIJ);CHKERRQ(ierr); ierr = PetscTypeCompare((PetscObject)A,MATSEQSBAIJ,&isSeqSBAIJ);CHKERRQ(ierr); if (lu->matstruc == DIFFERENT_NONZERO_PATTERN){ (F)->ops->solve = MatSolve_MUMPS; /* Initialize a MUMPS instance */ ierr = MPI_Comm_rank(((PetscObject)A)->comm, &lu->myid); ierr = MPI_Comm_size(((PetscObject)A)->comm,&lu->size);CHKERRQ(ierr); lu->id.job = JOB_INIT; ierr = MPI_Comm_dup(((PetscObject)A)->comm,&(lu->comm_mumps));CHKERRQ(ierr); lu->id.comm_fortran = MPI_Comm_c2f(lu->comm_mumps); /* Set mumps options */ ierr = PetscOptionsBegin(((PetscObject)A)->comm,((PetscObject)A)->prefix,"MUMPS Options","Mat");CHKERRQ(ierr); lu->id.par=1; /* host participates factorizaton and solve */ lu->id.sym=lu->sym; if (lu->sym == 2){ ierr = PetscOptionsInt("-mat_mumps_sym","SYM: (1,2)","None",lu->id.sym,&icntl,&flg);CHKERRQ(ierr); if (flg && icntl == 1) lu->id.sym=icntl; /* matrix is spd */ } #if defined(PETSC_USE_COMPLEX) zmumps_c(&lu->id); #else dmumps_c(&lu->id); #endif if (isSeqAIJ || isSeqSBAIJ){ lu->id.ICNTL(18) = 0; /* centralized assembled matrix input */ } else { lu->id.ICNTL(18) = 3; /* distributed assembled matrix input */ } icntl=-1; lu->id.ICNTL(4) = 0; /* level of printing; overwrite mumps default ICNTL(4)=2 */ ierr = PetscOptionsInt("-mat_mumps_icntl_4","ICNTL(4): level of printing (0 to 4)","None",lu->id.ICNTL(4),&icntl,&flg);CHKERRQ(ierr); if ((flg && icntl > 0) || PetscLogPrintInfo) { lu->id.ICNTL(4)=icntl; /* and use mumps default icntl(i), i=1,2,3 */ } else { /* no output */ lu->id.ICNTL(1) = 0; /* error message, default= 6 */ lu->id.ICNTL(2) = 0; /* output stream for diagnostic printing, statistics, and warning. default=0 */ lu->id.ICNTL(3) = 0; /* output stream for global information, default=6 */ } ierr = PetscOptionsInt("-mat_mumps_icntl_6","ICNTL(6): column permutation and/or scaling to get a zero-free diagonal (0 to 7)","None",lu->id.ICNTL(6),&lu->id.ICNTL(6),PETSC_NULL);CHKERRQ(ierr); icntl=-1; ierr = PetscOptionsInt("-mat_mumps_icntl_7","ICNTL(7): matrix ordering (0 to 7)","None",lu->id.ICNTL(7),&icntl,&flg);CHKERRQ(ierr); if (flg) { if (icntl== 1){ SETERRQ(PETSC_ERR_SUP,"pivot order be set by the user in PERM_IN -- not supported by the PETSc/MUMPS interface\n"); } else { lu->id.ICNTL(7) = icntl; } } ierr = PetscOptionsInt("-mat_mumps_icntl_8","ICNTL(8): scaling strategy (-2 to 7 or 77)","None",lu->id.ICNTL(8),&lu->id.ICNTL(8),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_9","ICNTL(9): A or A^T x=b to be solved. 1: A; otherwise: A^T","None",lu->id.ICNTL(9),&lu->id.ICNTL(9),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_10","ICNTL(10): max num of refinements","None",lu->id.ICNTL(10),&lu->id.ICNTL(10),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_11","ICNTL(11): statistics related to the linear system solved (via -ksp_view)","None",lu->id.ICNTL(11),&lu->id.ICNTL(11),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_12","ICNTL(12): efficiency control: defines the ordering strategy with scaling constraints (0 to 3","None",lu->id.ICNTL(12),&lu->id.ICNTL(12),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_13","ICNTL(13): efficiency control: with or without ScaLAPACK","None",lu->id.ICNTL(13),&lu->id.ICNTL(13),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_14","ICNTL(14): percentage of estimated workspace increase","None",lu->id.ICNTL(14),&lu->id.ICNTL(14),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_19","ICNTL(19): Schur complement","None",lu->id.ICNTL(19),&lu->id.ICNTL(19),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_22","ICNTL(22): in-core/out-of-core facility (0 or 1)","None",lu->id.ICNTL(22),&lu->id.ICNTL(22),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_23","ICNTL(23): max size of the working memory (MB) that can allocate per processor","None",lu->id.ICNTL(23),&lu->id.ICNTL(23),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_24","ICNTL(24): detection of null pivot rows (0 or 1)","None",lu->id.ICNTL(24),&lu->id.ICNTL(24),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_25","ICNTL(25): computation of a null space basis","None",lu->id.ICNTL(25),&lu->id.ICNTL(25),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_26","ICNTL(26): Schur options for right-hand side or solution vector","None",lu->id.ICNTL(26),&lu->id.ICNTL(26),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsInt("-mat_mumps_icntl_27","ICNTL(27): experimental parameter","None",lu->id.ICNTL(27),&lu->id.ICNTL(27),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsReal("-mat_mumps_cntl_1","CNTL(1): relative pivoting threshold","None",lu->id.CNTL(1),&lu->id.CNTL(1),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsReal("-mat_mumps_cntl_2","CNTL(2): stopping criterion of refinement","None",lu->id.CNTL(2),&lu->id.CNTL(2),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsReal("-mat_mumps_cntl_3","CNTL(3): absolute pivoting threshold","None",lu->id.CNTL(3),&lu->id.CNTL(3),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsReal("-mat_mumps_cntl_4","CNTL(4): value for static pivoting","None",lu->id.CNTL(4),&lu->id.CNTL(4),PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsReal("-mat_mumps_cntl_5","CNTL(5): fixation for null pivots","None",lu->id.CNTL(5),&lu->id.CNTL(5),PETSC_NULL);CHKERRQ(ierr); PetscOptionsEnd(); } /* define matrix A */ switch (lu->id.ICNTL(18)){ case 0: /* centralized assembled matrix input (size=1) */ if (!lu->myid) { if (isSeqAIJ){ Mat_SeqAIJ *aa = (Mat_SeqAIJ*)A->data; nz = aa->nz; ai = aa->i; aj = aa->j; lu->val = aa->a; } else if (isSeqSBAIJ) { Mat_SeqSBAIJ *aa = (Mat_SeqSBAIJ*)A->data; nz = aa->nz; ai = aa->i; aj = aa->j; lu->val = aa->a; } else { SETERRQ(PETSC_ERR_SUP,"No mumps factorization for this matrix type"); } if (lu->matstruc == DIFFERENT_NONZERO_PATTERN){ /* first numeric factorization, get irn and jcn */ ierr = PetscMalloc(nz*sizeof(PetscInt),&lu->irn);CHKERRQ(ierr); ierr = PetscMalloc(nz*sizeof(PetscInt),&lu->jcn);CHKERRQ(ierr); nz = 0; for (i=0; iirn[nz] = i+1; lu->jcn[nz] = (*aj)+1; aj++; nz++; } } } } break; case 3: /* distributed assembled matrix input (size>1) */ if (lu->matstruc == DIFFERENT_NONZERO_PATTERN){ valOnly = PETSC_FALSE; } else { valOnly = PETSC_TRUE; /* only update mat values, not row and col index */ } ierr = MatConvertToTriples(A,1,valOnly, &nnz, &lu->irn, &lu->jcn, &lu->val);CHKERRQ(ierr); break; default: SETERRQ(PETSC_ERR_SUP,"Matrix input format is not supported by MUMPS."); } /* analysis phase */ /*----------------*/ if (lu->matstruc == DIFFERENT_NONZERO_PATTERN){ lu->id.job = 1; lu->id.n = M; switch (lu->id.ICNTL(18)){ case 0: /* centralized assembled matrix input */ if (!lu->myid) { lu->id.nz =nz; lu->id.irn=lu->irn; lu->id.jcn=lu->jcn; if (lu->id.ICNTL(6)>1){ #if defined(PETSC_USE_COMPLEX) lu->id.a = (mumps_double_complex*)lu->val; #else lu->id.a = lu->val; #endif } } break; case 3: /* distributed assembled matrix input (size>1) */ lu->id.nz_loc = nnz; lu->id.irn_loc=lu->irn; lu->id.jcn_loc=lu->jcn; if (lu->id.ICNTL(6)>1) { #if defined(PETSC_USE_COMPLEX) lu->id.a_loc = (mumps_double_complex*)lu->val; #else lu->id.a_loc = lu->val; #endif } /* MUMPS only supports centralized rhs. Create scatter scat_rhs for repeated use in MatSolve() */ if (!lu->myid){ ierr = VecCreateSeq(PETSC_COMM_SELF,A->cmap->N,&lu->b_seq);CHKERRQ(ierr); ierr = ISCreateStride(PETSC_COMM_SELF,A->cmap->N,0,1,&is_iden);CHKERRQ(ierr); } else { ierr = VecCreateSeq(PETSC_COMM_SELF,0,&lu->b_seq);CHKERRQ(ierr); ierr = ISCreateStride(PETSC_COMM_SELF,0,0,1,&is_iden);CHKERRQ(ierr); } ierr = VecCreate(((PetscObject)A)->comm,&b);CHKERRQ(ierr); ierr = VecSetSizes(b,A->rmap->n,PETSC_DECIDE);CHKERRQ(ierr); ierr = VecSetFromOptions(b);CHKERRQ(ierr); ierr = VecScatterCreate(b,is_iden,lu->b_seq,is_iden,&lu->scat_rhs);CHKERRQ(ierr); ierr = ISDestroy(is_iden);CHKERRQ(ierr); ierr = VecDestroy(b);CHKERRQ(ierr); break; } #if defined(PETSC_USE_COMPLEX) zmumps_c(&lu->id); #else dmumps_c(&lu->id); #endif if (lu->id.INFOG(1) < 0) { SETERRQ1(PETSC_ERR_LIB,"Error reported by MUMPS in analysis phase: INFOG(1)=%d\n",lu->id.INFOG(1)); } } /* numerical factorization phase */ /*-------------------------------*/ lu->id.job = 2; if(!lu->id.ICNTL(18)) { if (!lu->myid) { #if defined(PETSC_USE_COMPLEX) lu->id.a = (mumps_double_complex*)lu->val; #else lu->id.a = lu->val; #endif } } else { #if defined(PETSC_USE_COMPLEX) lu->id.a_loc = (mumps_double_complex*)lu->val; #else lu->id.a_loc = lu->val; #endif } #if defined(PETSC_USE_COMPLEX) zmumps_c(&lu->id); #else dmumps_c(&lu->id); #endif if (lu->id.INFOG(1) < 0) { if (lu->id.INFO(1) == -13) { SETERRQ1(PETSC_ERR_LIB,"Error reported by MUMPS in numerical factorization phase: Cannot allocate required memory %d megabytes\n",lu->id.INFO(2)); } else { SETERRQ2(PETSC_ERR_LIB,"Error reported by MUMPS in numerical factorization phase: INFO(1)=%d, INFO(2)=%d\n",lu->id.INFO(1),lu->id.INFO(2)); } } if (!lu->myid && lu->id.ICNTL(16) > 0){ SETERRQ1(PETSC_ERR_LIB," lu->id.ICNTL(16):=%d\n",lu->id.INFOG(16)); } if (lu->size > 1){ if ((F)->factor == MAT_FACTOR_LU){ F_diag = ((Mat_MPIAIJ *)(F)->data)->A; } else { F_diag = ((Mat_MPISBAIJ *)(F)->data)->A; } F_diag->assembled = PETSC_TRUE; if (lu->nSolve){ ierr = VecScatterDestroy(lu->scat_sol);CHKERRQ(ierr); ierr = PetscFree(lu->id.sol_loc);CHKERRQ(ierr); ierr = VecDestroy(lu->x_seq);CHKERRQ(ierr); } } (F)->assembled = PETSC_TRUE; lu->matstruc = SAME_NONZERO_PATTERN; lu->CleanUpMUMPS = PETSC_TRUE; lu->nSolve = 0; PetscFunctionReturn(0); } /* Note the Petsc r and c permutations are ignored */ #undef __FUNCT__ #define __FUNCT__ "MatLUFactorSymbolic_AIJMUMPS" PetscErrorCode MatLUFactorSymbolic_AIJMUMPS(Mat F,Mat A,IS r,IS c,const MatFactorInfo *info) { Mat_MUMPS *lu = (Mat_MUMPS*)F->spptr; PetscFunctionBegin; lu->sym = 0; lu->matstruc = DIFFERENT_NONZERO_PATTERN; F->ops->lufactornumeric = MatFactorNumeric_MUMPS; PetscFunctionReturn(0); } /* Note the Petsc r permutation is ignored */ #undef __FUNCT__ #define __FUNCT__ "MatCholeskyFactorSymbolic_SBAIJMUMPS" PetscErrorCode MatCholeskyFactorSymbolic_SBAIJMUMPS(Mat F,Mat A,IS r,const MatFactorInfo *info) { Mat_MUMPS *lu = (Mat_MUMPS*)(F)->spptr; PetscFunctionBegin; lu->sym = 2; lu->matstruc = DIFFERENT_NONZERO_PATTERN; (F)->ops->choleskyfactornumeric = MatFactorNumeric_MUMPS; #if !defined(PETSC_USE_COMPLEX) (F)->ops->getinertia = MatGetInertia_SBAIJMUMPS; #endif PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatFactorInfo_MUMPS" PetscErrorCode MatFactorInfo_MUMPS(Mat A,PetscViewer viewer) { Mat_MUMPS *lu=(Mat_MUMPS*)A->spptr; PetscErrorCode ierr; PetscFunctionBegin; /* check if matrix is mumps type */ if (A->ops->solve != MatSolve_MUMPS) PetscFunctionReturn(0); ierr = PetscViewerASCIIPrintf(viewer,"MUMPS run parameters:\n");CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," SYM (matrix type): %d \n",lu->id.sym);CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," PAR (host participation): %d \n",lu->id.par);CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(1) (output for error): %d \n",lu->id.ICNTL(1));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(2) (output of diagnostic msg):%d \n",lu->id.ICNTL(2));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(3) (output for global info): %d \n",lu->id.ICNTL(3));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(4) (level of printing): %d \n",lu->id.ICNTL(4));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(5) (input mat struct): %d \n",lu->id.ICNTL(5));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(6) (matrix prescaling): %d \n",lu->id.ICNTL(6));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(7) (matrix ordering): %d \n",lu->id.ICNTL(7));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(8) (scalling strategy): %d \n",lu->id.ICNTL(8));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(9) (A/A^T x=b is solved): %d \n",lu->id.ICNTL(9));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(10) (max num of refinements): %d \n",lu->id.ICNTL(10));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(11) (error analysis): %d \n",lu->id.ICNTL(11));CHKERRQ(ierr); if (!lu->myid && lu->id.ICNTL(11)>0) { ierr = PetscPrintf(PETSC_COMM_SELF," RINFOG(4) (inf norm of input mat): %g\n",lu->id.RINFOG(4));CHKERRQ(ierr); ierr = PetscPrintf(PETSC_COMM_SELF," RINFOG(5) (inf norm of solution): %g\n",lu->id.RINFOG(5));CHKERRQ(ierr); ierr = PetscPrintf(PETSC_COMM_SELF," RINFOG(6) (inf norm of residual): %g\n",lu->id.RINFOG(6));CHKERRQ(ierr); ierr = PetscPrintf(PETSC_COMM_SELF," RINFOG(7),RINFOG(8) (backward error est): %g, %g\n",lu->id.RINFOG(7),lu->id.RINFOG(8));CHKERRQ(ierr); ierr = PetscPrintf(PETSC_COMM_SELF," RINFOG(9) (error estimate): %g \n",lu->id.RINFOG(9));CHKERRQ(ierr); ierr = PetscPrintf(PETSC_COMM_SELF," RINFOG(10),RINFOG(11)(condition numbers): %g, %g\n",lu->id.RINFOG(10),lu->id.RINFOG(11));CHKERRQ(ierr); } ierr = PetscViewerASCIIPrintf(viewer," ICNTL(12) (efficiency control): %d \n",lu->id.ICNTL(12));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(13) (efficiency control): %d \n",lu->id.ICNTL(13));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(14) (percentage of estimated workspace increase): %d \n",lu->id.ICNTL(14));CHKERRQ(ierr); /* ICNTL(15-17) not used */ ierr = PetscViewerASCIIPrintf(viewer," ICNTL(18) (input mat struct): %d \n",lu->id.ICNTL(18));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(19) (Shur complement info): %d \n",lu->id.ICNTL(19));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(20) (rhs sparse pattern): %d \n",lu->id.ICNTL(20));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(21) (solution struct): %d \n",lu->id.ICNTL(21));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(22) (in-core/out-of-core facility): %d \n",lu->id.ICNTL(22));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(23) (max size of memory can be allocated locally):%d \n",lu->id.ICNTL(23));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(24) (detection of null pivot rows): %d \n",lu->id.ICNTL(24));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(25) (computation of a null space basis): %d \n",lu->id.ICNTL(25));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(26) (Schur options for rhs or solution): %d \n",lu->id.ICNTL(26));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," ICNTL(27) (experimental parameter): %d \n",lu->id.ICNTL(27));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," CNTL(1) (relative pivoting threshold): %g \n",lu->id.CNTL(1));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," CNTL(2) (stopping criterion of refinement): %g \n",lu->id.CNTL(2));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," CNTL(3) (absolute pivoting threshold): %g \n",lu->id.CNTL(3));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," CNTL(4) (value of static pivoting): %g \n",lu->id.CNTL(4));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," CNTL(5) (fixation for null pivots): %g \n",lu->id.CNTL(5));CHKERRQ(ierr); /* infomation local to each processor */ if (!lu->myid) {ierr = PetscPrintf(PETSC_COMM_SELF, " RINFO(1) (local estimated flops for the elimination after analysis): \n");CHKERRQ(ierr);} ierr = PetscSynchronizedPrintf(((PetscObject)A)->comm," [%d] %g \n",lu->myid,lu->id.RINFO(1));CHKERRQ(ierr); ierr = PetscSynchronizedFlush(((PetscObject)A)->comm); if (!lu->myid) {ierr = PetscPrintf(PETSC_COMM_SELF, " RINFO(2) (local estimated flops for the assembly after factorization): \n");CHKERRQ(ierr);} ierr = PetscSynchronizedPrintf(((PetscObject)A)->comm," [%d] %g \n",lu->myid,lu->id.RINFO(2));CHKERRQ(ierr); ierr = PetscSynchronizedFlush(((PetscObject)A)->comm); if (!lu->myid) {ierr = PetscPrintf(PETSC_COMM_SELF, " RINFO(3) (local estimated flops for the elimination after factorization): \n");CHKERRQ(ierr);} ierr = PetscSynchronizedPrintf(((PetscObject)A)->comm," [%d] %g \n",lu->myid,lu->id.RINFO(3));CHKERRQ(ierr); ierr = PetscSynchronizedFlush(((PetscObject)A)->comm); if (!lu->myid) {ierr = PetscPrintf(PETSC_COMM_SELF, " INFO(15) (estimated size of (in MB) MUMPS internal data for running numerical factorization): \n");CHKERRQ(ierr);} ierr = PetscSynchronizedPrintf(((PetscObject)A)->comm," [%d] %d \n",lu->myid,lu->id.INFO(15));CHKERRQ(ierr); ierr = PetscSynchronizedFlush(((PetscObject)A)->comm); if (!lu->myid) {ierr = PetscPrintf(PETSC_COMM_SELF, " INFO(16) (size of (in MB) MUMPS internal data used during numerical factorization): \n");CHKERRQ(ierr);} ierr = PetscSynchronizedPrintf(((PetscObject)A)->comm," [%d] %d \n",lu->myid,lu->id.INFO(16));CHKERRQ(ierr); ierr = PetscSynchronizedFlush(((PetscObject)A)->comm); if (!lu->myid) {ierr = PetscPrintf(PETSC_COMM_SELF, " INFO(23) (num of pivots eliminated on this processor after factorization): \n");CHKERRQ(ierr);} ierr = PetscSynchronizedPrintf(((PetscObject)A)->comm," [%d] %d \n",lu->myid,lu->id.INFO(23));CHKERRQ(ierr); ierr = PetscSynchronizedFlush(((PetscObject)A)->comm); if (!lu->myid){ /* information from the host */ ierr = PetscViewerASCIIPrintf(viewer," RINFOG(1) (global estimated flops for the elimination after analysis): %g \n",lu->id.RINFOG(1));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," RINFOG(2) (global estimated flops for the assembly after factorization): %g \n",lu->id.RINFOG(2));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," RINFOG(3) (global estimated flops for the elimination after factorization): %g \n",lu->id.RINFOG(3));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(3) (estimated real workspace for factors on all processors after analysis): %d \n",lu->id.INFOG(3));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(4) (estimated integer workspace for factors on all processors after analysis): %d \n",lu->id.INFOG(4));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(5) (estimated maximum front size in the complete tree): %d \n",lu->id.INFOG(5));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(6) (number of nodes in the complete tree): %d \n",lu->id.INFOG(6));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(7) (ordering option effectively uese after analysis): %d \n",lu->id.INFOG(7));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(8) (structural symmetry in percent of the permuted matrix after analysis): %d \n",lu->id.INFOG(8));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(9) (total real/complex workspace to store the matrix factors after factorization): %d \n",lu->id.INFOG(9));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(10) (total integer space store the matrix factors after factorization): %d \n",lu->id.INFOG(10));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(11) (order of largest frontal matrix after factorization): %d \n",lu->id.INFOG(11));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(12) (number of off-diagonal pivots): %d \n",lu->id.INFOG(12));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(13) (number of delayed pivots after factorization): %d \n",lu->id.INFOG(13));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(14) (number of memory compress after factorization): %d \n",lu->id.INFOG(14));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(15) (number of steps of iterative refinement after solution): %d \n",lu->id.INFOG(15));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(16) (estimated size (in MB) of all MUMPS internal data for factorization after analysis: value on the most memory consuming processor): %d \n",lu->id.INFOG(16));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(17) (estimated size of all MUMPS internal data for factorization after analysis: sum over all processors): %d \n",lu->id.INFOG(17));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(18) (size of all MUMPS internal data allocated during factorization: value on the most memory consuming processor): %d \n",lu->id.INFOG(18));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(19) (size of all MUMPS internal data allocated during factorization: sum over all processors): %d \n",lu->id.INFOG(19));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(20) (estimated number of entries in the factors): %d \n",lu->id.INFOG(20));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(21) (size in MB of memory effectively used during factorization - value on the most memory consuming processor): %d \n",lu->id.INFOG(21));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(22) (size in MB of memory effectively used during factorization - sum over all processors): %d \n",lu->id.INFOG(22));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(23) (after analysis: value of ICNTL(6) effectively used): %d \n",lu->id.INFOG(23));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(24) (after analysis: value of ICNTL(12) effectively used): %d \n",lu->id.INFOG(24));CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer," INFOG(25) (after factorization: number of pivots modified by static pivoting): %d \n",lu->id.INFOG(25));CHKERRQ(ierr); } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatView_MUMPS" PetscErrorCode MatView_MUMPS(Mat A,PetscViewer viewer) { PetscErrorCode ierr; PetscTruth iascii; PetscViewerFormat format; PetscFunctionBegin; ierr = PetscTypeCompare((PetscObject)viewer,PETSC_VIEWER_ASCII,&iascii);CHKERRQ(ierr); if (iascii) { ierr = PetscViewerGetFormat(viewer,&format);CHKERRQ(ierr); if (format == PETSC_VIEWER_ASCII_INFO){ ierr = MatFactorInfo_MUMPS(A,viewer);CHKERRQ(ierr); } } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatGetInfo_MUMPS" PetscErrorCode MatGetInfo_MUMPS(Mat A,MatInfoType flag,MatInfo *info) { Mat_MUMPS *lu =(Mat_MUMPS*)A->spptr; PetscFunctionBegin; info->block_size = 1.0; info->nz_allocated = lu->id.INFOG(20); info->nz_used = lu->id.INFOG(20); info->nz_unneeded = 0.0; info->assemblies = 0.0; info->mallocs = 0.0; info->memory = 0.0; info->fill_ratio_given = 0; info->fill_ratio_needed = 0; info->factor_mallocs = 0; PetscFunctionReturn(0); } /*MC MAT_SOLVER_MUMPS - A matrix type providing direct solvers (LU and Cholesky) for distributed and sequential matrices via the external package MUMPS. Works with MATAIJ and MATSBAIJ matrices Options Database Keys: + -mat_mumps_sym <0,1,2> - 0 the matrix is unsymmetric, 1 symmetric positive definite, 2 symmetric . -mat_mumps_icntl_4 <0,...,4> - print level . -mat_mumps_icntl_6 <0,...,7> - matrix prescaling options (see MUMPS User's Guide) . -mat_mumps_icntl_7 <0,...,7> - matrix orderings (see MUMPS User's Guide) . -mat_mumps_icntl_9 <1,2> - A or A^T x=b to be solved: 1 denotes A, 2 denotes A^T . -mat_mumps_icntl_10 - maximum number of iterative refinements . -mat_mumps_icntl_11 - error analysis, a positive value returns statistics during -ksp_view . -mat_mumps_icntl_12 - efficiency control (see MUMPS User's Guide) . -mat_mumps_icntl_13 - efficiency control (see MUMPS User's Guide) . -mat_mumps_icntl_14 - efficiency control (see MUMPS User's Guide) . -mat_mumps_icntl_15 - efficiency control (see MUMPS User's Guide) . -mat_mumps_cntl_1 - relative pivoting threshold . -mat_mumps_cntl_2 - stopping criterion for refinement - -mat_mumps_cntl_3 - absolute pivoting threshold Level: beginner .seealso: PCFactorSetMatSolverPackage(), MatSolverPackage M*/ EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatFactorGetSolverPackage_mumps" PetscErrorCode MatFactorGetSolverPackage_mumps(Mat A,const MatSolverPackage *type) { PetscFunctionBegin; *type = MAT_SOLVER_MUMPS; PetscFunctionReturn(0); } EXTERN_C_END EXTERN_C_BEGIN /* The seq and mpi versions of this function are the same */ #undef __FUNCT__ #define __FUNCT__ "MatGetFactor_seqaij_mumps" PetscErrorCode MatGetFactor_seqaij_mumps(Mat A,MatFactorType ftype,Mat *F) { Mat B; PetscErrorCode ierr; Mat_MUMPS *mumps; PetscFunctionBegin; if (ftype != MAT_FACTOR_LU) { SETERRQ(PETSC_ERR_SUP,"Cannot use PETSc AIJ matrices with MUMPS Cholesky, use SBAIJ matrix"); } /* Create the factorization matrix */ ierr = MatCreate(((PetscObject)A)->comm,&B);CHKERRQ(ierr); ierr = MatSetSizes(B,A->rmap->n,A->cmap->n,A->rmap->N,A->cmap->N);CHKERRQ(ierr); ierr = MatSetType(B,((PetscObject)A)->type_name);CHKERRQ(ierr); ierr = MatSeqAIJSetPreallocation(B,0,PETSC_NULL);CHKERRQ(ierr); B->ops->lufactorsymbolic = MatLUFactorSymbolic_AIJMUMPS; B->ops->view = MatView_MUMPS; B->ops->getinfo = MatGetInfo_MUMPS; ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"MatFactorGetSolverPackage_C","MatFactorGetSolverPackage_mumps",MatFactorGetSolverPackage_mumps);CHKERRQ(ierr); B->factor = MAT_FACTOR_LU; ierr = PetscNewLog(B,Mat_MUMPS,&mumps);CHKERRQ(ierr); mumps->CleanUpMUMPS = PETSC_FALSE; mumps->isAIJ = PETSC_TRUE; mumps->scat_rhs = PETSC_NULL; mumps->scat_sol = PETSC_NULL; mumps->nSolve = 0; mumps->MatDestroy = B->ops->destroy; B->ops->destroy = MatDestroy_MUMPS; B->spptr = (void*)mumps; *F = B; PetscFunctionReturn(0); } EXTERN_C_END EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatGetFactor_mpiaij_mumps" PetscErrorCode MatGetFactor_mpiaij_mumps(Mat A,MatFactorType ftype,Mat *F) { Mat B; PetscErrorCode ierr; Mat_MUMPS *mumps; PetscFunctionBegin; if (ftype != MAT_FACTOR_LU) { SETERRQ(PETSC_ERR_SUP,"Cannot use PETSc AIJ matrices with MUMPS Cholesky, use SBAIJ matrix"); } /* Create the factorization matrix */ ierr = MatCreate(((PetscObject)A)->comm,&B);CHKERRQ(ierr); ierr = MatSetSizes(B,A->rmap->n,A->cmap->n,A->rmap->N,A->cmap->N);CHKERRQ(ierr); ierr = MatSetType(B,((PetscObject)A)->type_name);CHKERRQ(ierr); ierr = MatSeqAIJSetPreallocation(B,0,PETSC_NULL);CHKERRQ(ierr); ierr = MatMPIAIJSetPreallocation(B,0,PETSC_NULL,0,PETSC_NULL);CHKERRQ(ierr); B->ops->lufactorsymbolic = MatLUFactorSymbolic_AIJMUMPS; B->ops->view = MatView_MUMPS; ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"MatFactorGetSolverPackage_C","MatFactorGetSolverPackage_mumps",MatFactorGetSolverPackage_mumps);CHKERRQ(ierr); B->factor = MAT_FACTOR_LU; ierr = PetscNewLog(B,Mat_MUMPS,&mumps);CHKERRQ(ierr); mumps->CleanUpMUMPS = PETSC_FALSE; mumps->isAIJ = PETSC_TRUE; mumps->scat_rhs = PETSC_NULL; mumps->scat_sol = PETSC_NULL; mumps->nSolve = 0; mumps->MatDestroy = B->ops->destroy; B->ops->destroy = MatDestroy_MUMPS; B->spptr = (void*)mumps; *F = B; PetscFunctionReturn(0); } EXTERN_C_END EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatGetFactor_seqsbaij_mumps" PetscErrorCode MatGetFactor_seqsbaij_mumps(Mat A,MatFactorType ftype,Mat *F) { Mat B; PetscErrorCode ierr; Mat_MUMPS *mumps; PetscFunctionBegin; if (ftype != MAT_FACTOR_CHOLESKY) { SETERRQ(PETSC_ERR_SUP,"Cannot use PETSc SBAIJ matrices with MUMPS LU, use AIJ matrix"); } /* Create the factorization matrix */ ierr = MatCreate(((PetscObject)A)->comm,&B);CHKERRQ(ierr); ierr = MatSetSizes(B,A->rmap->n,A->cmap->n,A->rmap->N,A->cmap->N);CHKERRQ(ierr); ierr = MatSetType(B,((PetscObject)A)->type_name);CHKERRQ(ierr); ierr = MatSeqSBAIJSetPreallocation(B,1,0,PETSC_NULL);CHKERRQ(ierr); ierr = MatMPISBAIJSetPreallocation(B,1,0,PETSC_NULL,0,PETSC_NULL);CHKERRQ(ierr); B->ops->choleskyfactorsymbolic = MatCholeskyFactorSymbolic_SBAIJMUMPS; B->ops->view = MatView_MUMPS; ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"MatFactorGetSolverPackage_C","MatFactorGetSolverPackage_mumps",MatFactorGetSolverPackage_mumps);CHKERRQ(ierr); B->factor = MAT_FACTOR_CHOLESKY; ierr = PetscNewLog(B,Mat_MUMPS,&mumps);CHKERRQ(ierr); mumps->CleanUpMUMPS = PETSC_FALSE; mumps->isAIJ = PETSC_TRUE; mumps->scat_rhs = PETSC_NULL; mumps->scat_sol = PETSC_NULL; mumps->nSolve = 0; mumps->MatDestroy = B->ops->destroy; B->ops->destroy = MatDestroy_MUMPS; B->spptr = (void*)mumps; *F = B; PetscFunctionReturn(0); } EXTERN_C_END EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatGetFactor_mpisbaij_mumps" PetscErrorCode MatGetFactor_mpisbaij_mumps(Mat A,MatFactorType ftype,Mat *F) { Mat B; PetscErrorCode ierr; Mat_MUMPS *mumps; PetscFunctionBegin; if (ftype != MAT_FACTOR_CHOLESKY) { SETERRQ(PETSC_ERR_SUP,"Cannot use PETSc SBAIJ matrices with MUMPS LU, use AIJ matrix"); } /* Create the factorization matrix */ ierr = MatCreate(((PetscObject)A)->comm,&B);CHKERRQ(ierr); ierr = MatSetSizes(B,A->rmap->n,A->cmap->n,A->rmap->N,A->cmap->N);CHKERRQ(ierr); ierr = MatSetType(B,((PetscObject)A)->type_name);CHKERRQ(ierr); ierr = MatSeqSBAIJSetPreallocation(B,1,0,PETSC_NULL);CHKERRQ(ierr); ierr = MatMPISBAIJSetPreallocation(B,1,0,PETSC_NULL,0,PETSC_NULL);CHKERRQ(ierr); B->ops->choleskyfactorsymbolic = MatCholeskyFactorSymbolic_SBAIJMUMPS; B->ops->view = MatView_MUMPS; ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"MatFactorGetSolverPackage_C","MatFactorGetSolverPackage_mumps",MatFactorGetSolverPackage_mumps);CHKERRQ(ierr); B->factor = MAT_FACTOR_CHOLESKY; ierr = PetscNewLog(B,Mat_MUMPS,&mumps);CHKERRQ(ierr); mumps->CleanUpMUMPS = PETSC_FALSE; mumps->isAIJ = PETSC_TRUE; mumps->scat_rhs = PETSC_NULL; mumps->scat_sol = PETSC_NULL; mumps->nSolve = 0; mumps->MatDestroy = B->ops->destroy; B->ops->destroy = MatDestroy_MUMPS; B->spptr = (void*)mumps; *F = B; PetscFunctionReturn(0); } EXTERN_C_END