/*! @file sp_preorder.c * \brief Permute and performs functions on columns of orginal matrix */ #include "slu_ddefs.h" /*! \brief * *

 * Purpose
 * =======
 *
 * sp_preorder() permutes the columns of the original matrix. It performs
 * the following steps:
 *
 *    1. Apply column permutation perm_c[] to A's column pointers to form AC;
 *
 *    2. If options->Fact = DOFACT, then
 *       (1) Compute column elimination tree etree[] of AC'AC;
 *       (2) Post order etree[] to get a postordered elimination tree etree[],
 *           and a postorder permutation post[];
 *       (3) Apply post[] permutation to columns of AC;
 *       (4) Overwrite perm_c[] with the product perm_c * post.
 *
 * Arguments
 * =========
 *
 * options (input) superlu_options_t*
 *         Specifies whether or not the elimination tree will be re-used.
 *         If options->Fact == DOFACT, this means first time factor A, 
 *         etree is computed, postered, and output.
 *         Otherwise, re-factor A, etree is input, unchanged on exit.
 *
 * A       (input) SuperMatrix*
 *         Matrix A in A*X=B, of dimension (A->nrow, A->ncol). The number
 *         of the linear equations is A->nrow. Currently, the type of A can be:
 *         Stype = NC or SLU_NCP; Mtype = SLU_GE.
 *         In the future, more general A may be handled.
 *
 * perm_c  (input/output) int*
 *	   Column permutation vector of size A->ncol, which defines the 
 *         permutation matrix Pc; perm_c[i] = j means column i of A is 
 *         in position j in A*Pc.
 *         If options->Fact == DOFACT, perm_c is both input and output.
 *         On output, it is changed according to a postorder of etree.
 *         Otherwise, perm_c is input.
 *
 * etree   (input/output) int*
 *         Elimination tree of Pc'*A'*A*Pc, dimension A->ncol.
 *         If options->Fact == DOFACT, etree is an output argument,
 *         otherwise it is an input argument.
 *         Note: etree is a vector of parent pointers for a forest whose
 *         vertices are the integers 0 to A->ncol-1; etree[root]==A->ncol.
 *
 * AC      (output) SuperMatrix*
 *         The resulting matrix after applied the column permutation
 *         perm_c[] to matrix A. The type of AC can be:
 *         Stype = SLU_NCP; Dtype = A->Dtype; Mtype = SLU_GE.
 *

*/ void sp_preorder(superlu_options_t *options, SuperMatrix *A, int *perm_c, int *etree, SuperMatrix *AC) { NCformat *Astore; NCPformat *ACstore; int *iwork, *post; register int n, i; n = A->ncol; /* Apply column permutation perm_c to A's column pointers so to obtain NCP format in AC = A*Pc. */ AC->Stype = SLU_NCP; AC->Dtype = A->Dtype; AC->Mtype = A->Mtype; AC->nrow = A->nrow; AC->ncol = A->ncol; Astore = A->Store; ACstore = AC->Store = (void *) SUPERLU_MALLOC( sizeof(NCPformat) ); if ( !ACstore ) ABORT("SUPERLU_MALLOC fails for ACstore"); ACstore->nnz = Astore->nnz; ACstore->nzval = Astore->nzval; ACstore->rowind = Astore->rowind; ACstore->colbeg = (int*) SUPERLU_MALLOC(n*sizeof(int)); if ( !(ACstore->colbeg) ) ABORT("SUPERLU_MALLOC fails for ACstore->colbeg"); ACstore->colend = (int*) SUPERLU_MALLOC(n*sizeof(int)); if ( !(ACstore->colend) ) ABORT("SUPERLU_MALLOC fails for ACstore->colend"); #ifdef DEBUG print_int_vec("pre_order:", n, perm_c); check_perm("Initial perm_c", n, perm_c); #endif for (i = 0; i < n; i++) { ACstore->colbeg[perm_c[i]] = Astore->colptr[i]; ACstore->colend[perm_c[i]] = Astore->colptr[i+1]; } if ( options->Fact == DOFACT ) { #undef ETREE_ATplusA #ifdef ETREE_ATplusA /*-------------------------------------------- COMPUTE THE ETREE OF Pc*(A'+A)*Pc'. --------------------------------------------*/ int *b_colptr, *b_rowind, bnz, j; int *c_colbeg, *c_colend; /*printf("Use etree(A'+A)\n");*/ /* Form B = A + A'. */ at_plus_a(n, Astore->nnz, Astore->colptr, Astore->rowind, &bnz, &b_colptr, &b_rowind); /* Form C = Pc*B*Pc'. */ c_colbeg = (int*) SUPERLU_MALLOC(2*n*sizeof(int)); c_colend = c_colbeg + n; if (!c_colbeg ) ABORT("SUPERLU_MALLOC fails for c_colbeg/c_colend"); for (i = 0; i < n; i++) { c_colbeg[perm_c[i]] = b_colptr[i]; c_colend[perm_c[i]] = b_colptr[i+1]; } for (j = 0; j < n; ++j) { for (i = c_colbeg[j]; i < c_colend[j]; ++i) { b_rowind[i] = perm_c[b_rowind[i]]; } } /* Compute etree of C. */ sp_symetree(c_colbeg, c_colend, b_rowind, n, etree); SUPERLU_FREE(b_colptr); if ( bnz ) SUPERLU_FREE(b_rowind); SUPERLU_FREE(c_colbeg); #else /*-------------------------------------------- COMPUTE THE COLUMN ELIMINATION TREE. --------------------------------------------*/ sp_coletree(ACstore->colbeg, ACstore->colend, ACstore->rowind, A->nrow, A->ncol, etree); #endif #ifdef DEBUG print_int_vec("etree:", n, etree); #endif /* In symmetric mode, do not do postorder here. */ if ( options->SymmetricMode == NO ) { /* Post order etree */ post = (int *) TreePostorder(n, etree); /* for (i = 0; i < n+1; ++i) inv_post[post[i]] = i; iwork = post; */ #ifdef DEBUG print_int_vec("post:", n+1, post); check_perm("post", n, post); #endif iwork = (int*) SUPERLU_MALLOC((n+1)*sizeof(int)); if ( !iwork ) ABORT("SUPERLU_MALLOC fails for iwork[]"); /* Renumber etree in postorder */ for (i = 0; i < n; ++i) iwork[post[i]] = post[etree[i]]; for (i = 0; i < n; ++i) etree[i] = iwork[i]; #ifdef DEBUG print_int_vec("postorder etree:", n, etree); #endif /* Postmultiply A*Pc by post[] */ for (i = 0; i < n; ++i) iwork[post[i]] = ACstore->colbeg[i]; for (i = 0; i < n; ++i) ACstore->colbeg[i] = iwork[i]; for (i = 0; i < n; ++i) iwork[post[i]] = ACstore->colend[i]; for (i = 0; i < n; ++i) ACstore->colend[i] = iwork[i]; for (i = 0; i < n; ++i) iwork[i] = post[perm_c[i]]; /* product of perm_c and post */ for (i = 0; i < n; ++i) perm_c[i] = iwork[i]; #ifdef DEBUG print_int_vec("Pc*post:", n, perm_c); check_perm("final perm_c", n, perm_c); #endif SUPERLU_FREE (post); SUPERLU_FREE (iwork); } /* end postordering */ } /* if options->Fact == DOFACT ... */ } int check_perm(char *what, int n, int *perm) { register int i; int *marker; marker = (int *) calloc(n, sizeof(int)); for (i = 0; i < n; ++i) { if ( marker[perm[i]] == 1 || perm[i] >= n ) { printf("%s: Not a valid PERM[%d] = %d\n", what, i, perm[i]); ABORT("check_perm"); } else { marker[perm[i]] = 1; } } SUPERLU_FREE(marker); return 0; }