// CXSparse/Source/cs_maxtrans: maximum transversal of a graph // CXSparse, Copyright (c) 2006-2022, Timothy A. Davis. All Rights Reserved. // SPDX-License-Identifier: LGPL-2.1+ #include "cs.h" /* find an augmenting path starting at column k and extend the match if found */ static void cs_augment (CS_INT k, const cs *A, CS_INT *jmatch, CS_INT *cheap, CS_INT *w, CS_INT *js, CS_INT *is, CS_INT *ps) { CS_INT found = 0, p, i = -1, *Ap = A->p, *Ai = A->i, head = 0, j ; js [0] = k ; /* start with just node k in jstack */ while (head >= 0) { /* --- Start (or continue) depth-first-search at node j ------------- */ j = js [head] ; /* get j from top of jstack */ if (w [j] != k) /* 1st time j visited for kth path */ { w [j] = k ; /* mark j as visited for kth path */ for (p = cheap [j] ; p < Ap [j+1] && !found ; p++) { i = Ai [p] ; /* try a cheap assignment (i,j) */ found = (jmatch [i] == -1) ; } cheap [j] = p ; /* start here next time j is traversed*/ if (found) { is [head] = i ; /* column j matched with row i */ break ; /* end of augmenting path */ } ps [head] = Ap [j] ; /* no cheap match: start dfs for j */ } /* --- Depth-first-search of neighbors of j ------------------------- */ for (p = ps [head] ; p < Ap [j+1] ; p++) { i = Ai [p] ; /* consider row i */ if (w [jmatch [i]] == k) continue ; /* skip jmatch [i] if marked */ ps [head] = p + 1 ; /* pause dfs of node j */ is [head] = i ; /* i will be matched with j if found */ js [++head] = jmatch [i] ; /* start dfs at column jmatch [i] */ break ; } if (p == Ap [j+1]) head-- ; /* node j is done; pop from stack */ } /* augment the match if path found: */ if (found) for (p = head ; p >= 0 ; p--) jmatch [is [p]] = js [p] ; } /* find a maximum transveral */ CS_INT *cs_maxtrans (const cs *A, CS_INT seed) /*[jmatch [0..m-1]; imatch [0..n-1]]*/ { CS_INT i, j, k, n, m, p, n2 = 0, m2 = 0, *Ap, *jimatch, *w, *cheap, *js, *is, *ps, *Ai, *Cp, *jmatch, *imatch, *q ; cs *C ; if (!CS_CSC (A)) return (NULL) ; /* check inputs */ n = A->n ; m = A->m ; Ap = A->p ; Ai = A->i ; w = jimatch = cs_calloc (m+n, sizeof (CS_INT)) ; /* allocate result */ if (!jimatch) return (NULL) ; for (k = 0, j = 0 ; j < n ; j++) /* count nonempty rows and columns */ { n2 += (Ap [j] < Ap [j+1]) ; for (p = Ap [j] ; p < Ap [j+1] ; p++) { w [Ai [p]] = 1 ; k += (j == Ai [p]) ; /* count entries already on diagonal */ } } if (k == CS_MIN (m,n)) /* quick return if diagonal zero-free */ { jmatch = jimatch ; imatch = jimatch + m ; for (i = 0 ; i < k ; i++) jmatch [i] = i ; for ( ; i < m ; i++) jmatch [i] = -1 ; for (j = 0 ; j < k ; j++) imatch [j] = j ; for ( ; j < n ; j++) imatch [j] = -1 ; return (cs_idone (jimatch, NULL, NULL, 1)) ; } for (i = 0 ; i < m ; i++) m2 += w [i] ; C = (m2 < n2) ? cs_transpose (A,0) : ((cs *) A) ; /* transpose if needed */ if (!C) return (cs_idone (jimatch, (m2 < n2) ? C : NULL, NULL, 0)) ; n = C->n ; m = C->m ; Cp = C->p ; jmatch = (m2 < n2) ? jimatch + n : jimatch ; imatch = (m2 < n2) ? jimatch : jimatch + m ; w = cs_malloc (5*n, sizeof (CS_INT)) ; /* get workspace */ if (!w) return (cs_idone (jimatch, (m2 < n2) ? C : NULL, w, 0)) ; cheap = w + n ; js = w + 2*n ; is = w + 3*n ; ps = w + 4*n ; for (j = 0 ; j < n ; j++) cheap [j] = Cp [j] ; /* for cheap assignment */ for (j = 0 ; j < n ; j++) w [j] = -1 ; /* all columns unflagged */ for (i = 0 ; i < m ; i++) jmatch [i] = -1 ; /* nothing matched yet */ q = cs_randperm (n, seed) ; /* q = random permutation */ for (k = 0 ; k < n ; k++) /* augment, starting at column q[k] */ { cs_augment (q ? q [k]: k, C, jmatch, cheap, w, js, is, ps) ; } cs_free (q) ; for (j = 0 ; j < n ; j++) imatch [j] = -1 ; /* find row match */ for (i = 0 ; i < m ; i++) if (jmatch [i] >= 0) imatch [jmatch [i]] = i ; return (cs_idone (jimatch, (m2 < n2) ? C : NULL, w, 1)) ; }