/* ========================================================================== */ /* === BTF_ORDER ============================================================ */ /* ========================================================================== */ /* Find a permutation P and Q to permute a square sparse matrix into upper block * triangular form. A(P,Q) will contain a zero-free diagonal if A has * structural full-rank. Otherwise, the number of nonzeros on the diagonal of * A(P,Q) will be maximized, and will equal the structural rank of A. * * Q[k] will be "flipped" if a zero-free diagonal was not found. Q[k] will be * negative, and j = BTF_UNFLIP (Q [k]) gives the corresponding permutation. * * R defines the block boundaries of A(P,Q). The kth block consists of rows * and columns R[k] to R[k+1]-1. * * If maxwork > 0 on input, then the work performed in btf_maxtrans is limited * to maxwork*nnz(A) (excluding the "cheap match" phase, which can take another * nnz(A) work). On output, the work parameter gives the actual work performed, * or -1 if the limit was reached. In the latter case, the diagonal of A(P,Q) * might not be zero-free, and the number of nonzeros on the diagonal of A(P,Q) * might not be equal to the structural rank. * * See btf.h for more details. * * By Tim Davis. Copyright (c) 2004-2007, University of Florida. * with support from Sandia National Laboratories. All Rights Reserved. */ #include "btf.h" #include "btf_internal.h" /* This function only operates on square matrices (either structurally full- * rank, or structurally rank deficient). */ Int BTF(order) /* returns number of blocks found */ ( /* input, not modified: */ Int n, /* A is n-by-n in compressed column form */ Int Ap [ ], /* size n+1 */ Int Ai [ ], /* size nz = Ap [n] */ double maxwork, /* do at most maxwork*nnz(A) work in the maximum * transversal; no limit if <= 0 */ /* output, not defined on input */ double *work, /* work performed in maxtrans, or -1 if limit reached */ Int P [ ], /* size n, row permutation */ Int Q [ ], /* size n, column permutation */ Int R [ ], /* size n+1. block b is in rows/cols R[b] ... R[b+1]-1 */ Int *nmatch, /* # nonzeros on diagonal of P*A*Q */ /* workspace, not defined on input or output */ Int Work [ ] /* size 5n */ ) { Int *Flag ; Int nblocks, i, j, nbadcol ; /* ---------------------------------------------------------------------- */ /* compute the maximum matching */ /* ---------------------------------------------------------------------- */ /* if maxwork > 0, then a maximum matching might not be found */ *nmatch = BTF(maxtrans) (n, n, Ap, Ai, maxwork, work, Q, Work) ; /* ---------------------------------------------------------------------- */ /* complete permutation if the matrix is structurally singular */ /* ---------------------------------------------------------------------- */ /* Since the matrix is square, ensure BTF_UNFLIP(Q[0..n-1]) is a * permutation of the columns of A so that A has as many nonzeros on the * diagonal as possible. */ if (*nmatch < n) { /* get a size-n work array */ Flag = Work + n ; for (j = 0 ; j < n ; j++) { Flag [j] = 0 ; } /* flag all matched columns */ for (i = 0 ; i < n ; i++) { j = Q [i] ; if (j != EMPTY) { /* row i and column j are matched to each other */ Flag [j] = 1 ; } } /* make a list of all unmatched columns, in Work [0..nbadcol-1] */ nbadcol = 0 ; for (j = n-1 ; j >= 0 ; j--) { if (!Flag [j]) { /* j is matched to nobody */ Work [nbadcol++] = j ; } } ASSERT (*nmatch + nbadcol == n) ; /* make an assignment for each unmatched row */ for (i = 0 ; i < n ; i++) { if (Q [i] == EMPTY && nbadcol > 0) { /* get an unmatched column j */ j = Work [--nbadcol] ; /* assign j to row i and flag the entry by "flipping" it */ Q [i] = BTF_FLIP (j) ; } } } /* The permutation of a square matrix can be recovered as follows: Row i is * matched with column j, where j = BTF_UNFLIP (Q [i]) and where j * will always be in the valid range 0 to n-1. The entry A(i,j) is zero * if BTF_ISFLIPPED (Q [i]) is true, and nonzero otherwise. nmatch * is the number of entries in the Q array that are non-negative. */ /* ---------------------------------------------------------------------- */ /* find the strongly connected components */ /* ---------------------------------------------------------------------- */ nblocks = BTF(strongcomp) (n, Ap, Ai, Q, P, R, Work) ; return (nblocks) ; }