/************************************************************************* * Copyright (c) 2011 AT&T Intellectual Property * All rights reserved. This program and the accompanying materials * are made available under the terms of the Eclipse Public License v1.0 * which accompanies this distribution, and is available at * https://www.eclipse.org/legal/epl-v10.html * * Contributors: Details at https://graphviz.org *************************************************************************/ /* * build edge_t concentrators for parallel edges with a common endpoint */ #include #include #define UP 0 #define DOWN 1 static bool samedir(edge_t * e, edge_t * f) { edge_t *e0, *f0; for (e0 = e; e0 != NULL && ED_edge_type(e0) != NORMAL; e0 = ED_to_orig(e0)); if (e0 == NULL) return false; for (f0 = f; f0 != NULL && ED_edge_type(f0) != NORMAL; f0 = ED_to_orig(f0)); if (f0 == NULL) return false; if (ED_conc_opp_flag(e0)) return false; if (ED_conc_opp_flag(f0)) return false; return ((ND_rank(agtail(f0)) - ND_rank(aghead(f0))) * (ND_rank(agtail(e0)) - ND_rank(aghead(e0))) > 0); } static bool downcandidate(node_t * v) { return ND_node_type(v) == VIRTUAL && ND_in(v).size == 1 && ND_out(v).size == 1 && ND_label(v) == NULL; } static bool bothdowncandidates(node_t * u, node_t * v) { edge_t *e, *f; e = ND_in(u).list[0]; f = ND_in(v).list[0]; if (downcandidate(v) && agtail(e) == agtail(f)) { return samedir(e, f) && portcmp(ED_tail_port(e), ED_tail_port(f)) == 0; } return false; } static bool upcandidate(node_t * v) { return ND_node_type(v) == VIRTUAL && ND_out(v).size == 1 && ND_in(v).size == 1 && ND_label(v) == NULL; } static bool bothupcandidates(node_t * u, node_t * v) { edge_t *e, *f; e = ND_out(u).list[0]; f = ND_out(v).list[0]; if (upcandidate(v) && aghead(e) == aghead(f)) { return samedir(e, f) && portcmp(ED_head_port(e), ED_head_port(f)) == 0; } return false; } static void mergevirtual(graph_t * g, int r, int lpos, int rpos, int dir) { int i, k; node_t *left, *right; edge_t *e, *f, *e0; left = GD_rank(g)[r].v[lpos]; /* merge all right nodes into the leftmost one */ for (i = lpos + 1; i <= rpos; i++) { right = GD_rank(g)[r].v[i]; if (dir == DOWN) { while ((e = ND_out(right).list[0])) { for (k = 0; (f = ND_out(left).list[k]); k++) if (aghead(f) == aghead(e)) break; if (f == NULL) f = virtual_edge(left, aghead(e), e); while ((e0 = ND_in(right).list[0])) { merge_oneway(e0, f); /*ED_weight(f) += ED_weight(e0); */ delete_fast_edge(e0); } delete_fast_edge(e); } } else { while ((e = ND_in(right).list[0])) { for (k = 0; (f = ND_in(left).list[k]); k++) if (agtail(f) == agtail(e)) break; if (f == NULL) f = virtual_edge(agtail(e), left, e); while ((e0 = ND_out(right).list[0])) { merge_oneway(e0, f); delete_fast_edge(e0); } delete_fast_edge(e); } } assert(ND_in(right).size + ND_out(right).size == 0); delete_fast_node(g, right); } k = lpos + 1; i = rpos + 1; while (i < GD_rank(g)[r].n) { node_t *n; n = GD_rank(g)[r].v[k] = GD_rank(g)[r].v[i]; ND_order(n) = k; k++; i++; } GD_rank(g)[r].n = k; GD_rank(g)[r].v[k] = NULL; } static void infuse(graph_t * g, node_t * n) { node_t *lead; lead = GD_rankleader(g)[ND_rank(n)]; if (lead == NULL || ND_order(lead) > ND_order(n)) GD_rankleader(g)[ND_rank(n)] = n; } static int rebuild_vlists(graph_t * g) { int c, i, r, maxi; node_t *n, *lead; edge_t *rep; for (r = GD_minrank(g); r <= GD_maxrank(g); r++) GD_rankleader(g)[r] = NULL; dot_scan_ranks(g); for (n = agfstnode(g); n; n = agnxtnode(g, n)) { infuse(g, n); for (edge_t *e = agfstout(g, n); e; e = agnxtout(g, e)) { for (rep = e; ED_to_virt(rep); rep = ED_to_virt(rep)); while (rep != NULL && ND_rank(aghead(rep)) < ND_rank(aghead(e))) { infuse(g, aghead(rep)); rep = ND_out(aghead(rep)).list[0]; } } } for (r = GD_minrank(g); r <= GD_maxrank(g); r++) { lead = GD_rankleader(g)[r]; if (lead == NULL) { agerrorf("rebuild_vlists: lead is null for rank %d\n", r); return -1; } else if (GD_rank(dot_root(g))[r].v[ND_order(lead)] != lead) { agerrorf("rebuild_vlists: rank lead %s not in order %d of rank %d\n", agnameof(lead), ND_order(lead), r); return -1; } GD_rank(g)[r].v = GD_rank(dot_root(g))[r].v + ND_order((GD_rankleader(g)[r])); maxi = -1; for (i = 0; i < GD_rank(g)[r].n; i++) { if ((n = GD_rank(g)[r].v[i]) == NULL) break; if (ND_node_type(n) == NORMAL) { if (agcontains(g, n)) maxi = i; else break; } else { edge_t *e; for (e = ND_in(n).list[0]; e && ED_to_orig(e); e = ED_to_orig(e)); if (e && agcontains(g, agtail(e)) && agcontains(g, aghead(e))) maxi = i; } } if (maxi == -1) agwarningf("degenerate concentrated rank %s,%d\n", agnameof(g), r); GD_rank(g)[r].n = maxi + 1; } for (c = 1; c <= GD_n_cluster(g); c++) { int ret = rebuild_vlists(GD_clust(g)[c]); if (ret != 0) { return ret; } } return 0; } void dot_concentrate(graph_t * g) { int c, r, leftpos, rightpos; node_t *left, *right; if (GD_maxrank(g) - GD_minrank(g) <= 1) return; /* this is the downward looking pass. r is a candidate rank. */ for (r = 1; GD_rank(g)[r + 1].n; r++) { for (leftpos = 0; leftpos < GD_rank(g)[r].n; leftpos++) { left = GD_rank(g)[r].v[leftpos]; if (!downcandidate(left)) continue; for (rightpos = leftpos + 1; rightpos < GD_rank(g)[r].n; rightpos++) { right = GD_rank(g)[r].v[rightpos]; if (!bothdowncandidates(left, right)) break; } if (rightpos - leftpos > 1) mergevirtual(g, r, leftpos, rightpos - 1, DOWN); } } /* this is the corresponding upward pass */ while (r > 0) { for (leftpos = 0; leftpos < GD_rank(g)[r].n; leftpos++) { left = GD_rank(g)[r].v[leftpos]; if (!upcandidate(left)) continue; for (rightpos = leftpos + 1; rightpos < GD_rank(g)[r].n; rightpos++) { right = GD_rank(g)[r].v[rightpos]; if (!bothupcandidates(left, right)) break; } if (rightpos - leftpos > 1) mergevirtual(g, r, leftpos, rightpos - 1, UP); } r--; } for (c = 1; c <= GD_n_cluster(g); c++) { if (rebuild_vlists(GD_clust(g)[c]) != 0) { agerr(AGPREV, "concentrate=true may not work correctly.\n"); return; } } }