/* * vim: ts=4 sw=4 et tw=0 wm=0 * * libcola - A library providing force-directed network layout using the * stress-majorization method subject to separation constraints. * * Copyright (C) 2006-2008 Monash University * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library in the file LICENSE; if not, * write to the Free Software Foundation, Inc., 59 Temple Place, * Suite 330, Boston, MA 02111-1307 USA * */ #include #include #include #include #include #include "graphlayouttest.h" using namespace std; using namespace cola; using namespace cycle_detector; using vpsc::Rectangle; int main() { CycleDetector *cd; Edges case_a, case_b, case_c, case_d, case_e, case_f, case_g; CyclicEdges *cycles = nullptr; vector rs; unsigned V; // create case A // case A consists of a basic graph where the start point is a source cout << endl << "ENTERING CASE A" << endl; V = 5; case_a.push_back(Edge(0, 1)); case_a.push_back(Edge(1, 2)); case_a.push_back(Edge(2, 3)); case_a.push_back(Edge(3, 4)); case_a.push_back(Edge(4, 1)); // detect the cycles cd = new CycleDetector(V, &case_a); cycles = cd->detect_cycles(); if (cycles != nullptr) { cout << "cycles->size(): " << cycles->size() << endl; for (unsigned i = 0; i < case_a.size(); i++) { // print out the cycles if ((*cycles)[i]) cout << "Cyclic edge found: (" << case_a[i].first << ", " << case_a[i].second << ")" << endl; } cout << endl; // output a picture rs.push_back(new Rectangle(10,10+5,10,10+5)); rs.push_back(new Rectangle(30,30+5,30,30+5)); rs.push_back(new Rectangle(30,30+5,60,60+5)); rs.push_back(new Rectangle(65,65+5,60,60+5)); rs.push_back(new Rectangle(65,65+5,30,30+5)); assert(rs.size() == V); output_svg(rs, case_a, "cycle_detector_case_a.svg", false, true, cycles); for (unsigned i = 0; i < rs.size(); i++) { delete rs[i]; } rs.clear(); delete cycles; } else { cout << "No cycles found" << endl; } // create case B // case B is the same graph of case A but with more elements cout << endl << "ENTERING CASE B" << endl; V = 7; case_b.push_back(Edge(0, 1)); case_b.push_back(Edge(1, 2)); case_b.push_back(Edge(2, 3)); case_b.push_back(Edge(3, 4)); case_b.push_back(Edge(4, 1)); case_b.push_back(Edge(5, 2)); case_b.push_back(Edge(6, 5)); // detect the cycles cd->mod_graph(V, &case_b); cycles = cd->detect_cycles(); if (cycles != nullptr) { cout << "cycles->size(): " << cycles->size() << endl; for (unsigned i = 0; i < case_b.size(); i++) { // print out the cycles if ((*cycles)[i]) cout << "Cyclic edge found: (" << case_b[i].first << ", " << case_b[i].second << ")" << endl; } cout << endl; // output a picture rs.push_back(new Rectangle(10,10+5,10,10+5)); rs.push_back(new Rectangle(30,30+5,30,30+5)); rs.push_back(new Rectangle(30,30+5,60,60+5)); rs.push_back(new Rectangle(65,65+5,60,60+5)); rs.push_back(new Rectangle(65,65+5,30,30+5)); rs.push_back(new Rectangle(30,30+5,90,90+5)); rs.push_back(new Rectangle(65,65+5,90,90+5)); assert(rs.size() == V); output_svg(rs, case_b, "cycle_detector_case_b.svg", false, true, cycles); for (unsigned i = 0; i < rs.size(); i++) { delete rs[i]; } rs.clear(); delete cycles; } // create case C // case C is a more complicated graph with nested cycles cout << endl << "ENTERING CASE C" << endl; V = 14; case_c.push_back(Edge(0, 1)); case_c.push_back(Edge(0, 5)); case_c.push_back(Edge(0, 6)); case_c.push_back(Edge(2, 0)); case_c.push_back(Edge(3, 5)); case_c.push_back(Edge(4, 3)); case_c.push_back(Edge(5, 4)); case_c.push_back(Edge(5, 13)); case_c.push_back(Edge(6, 2)); case_c.push_back(Edge(6, 9)); case_c.push_back(Edge(7, 6)); case_c.push_back(Edge(8, 7)); case_c.push_back(Edge(9, 10)); case_c.push_back(Edge(9, 11)); case_c.push_back(Edge(9, 12)); case_c.push_back(Edge(10, 6)); case_c.push_back(Edge(12, 10)); case_c.push_back(Edge(13, 4)); // detect the cycles //cd = new CycleDetector(V, &case_c); cd->mod_graph(V, &case_c); cycles = cd->detect_cycles(); if (cycles != nullptr) { cout << "cycles->size(): " << cycles->size() << endl; for (unsigned i = 0; i < case_c.size(); i++) { // print out the cycles if ((*cycles)[i]) cout << "Cyclic edge found: (" << case_c[i].first << ", " << case_c[i].second << ")" << endl; } cout << endl; // output a picture rs.push_back(new Rectangle(10,10+5,10,10+5)); // node 0 rs.push_back(new Rectangle(20,20+5,40,40+5)); // node 1 rs.push_back(new Rectangle(40,40+5,30,30+5)); // node 2 rs.push_back(new Rectangle(30,30+5,60,60+5)); // node 3 rs.push_back(new Rectangle(60,60+5,60,60+5)); // node 4 rs.push_back(new Rectangle(10,10+5,90,90+5)); // node 5 rs.push_back(new Rectangle(80,80+5,15,15+5)); // node 6 rs.push_back(new Rectangle(110,110+5,15,15+5)); // node 7 rs.push_back(new Rectangle(140,140+5,15,15+5)); // node 8 rs.push_back(new Rectangle(110,110+5,60,60+5)); // node 9 rs.push_back(new Rectangle(100,100+5,85,85+5)); // node 10 rs.push_back(new Rectangle(140,140+5,50,50+5)); // node 11 rs.push_back(new Rectangle(140,140+5,70,70+5)); // node 12 rs.push_back(new Rectangle(45,45+5,90,90+5)); // node 13 assert(rs.size() == V); output_svg(rs, case_c, "cycle_detector_case_c.svg", false, true, cycles); for(int i = 0; i < V; i++) { delete rs[i]; } rs.clear(); delete cycles; } // create case D // case D consists of the same graph as case A but with a different starting location cout << endl << "ENTERING CASE D" << endl; V = 5; case_d.push_back(Edge(0, 1)); case_d.push_back(Edge(1, 2)); case_d.push_back(Edge(2, 3)); case_d.push_back(Edge(3, 0)); case_d.push_back(Edge(4, 1)); // detect the cycles cd->mod_graph(V, &case_d); cycles = cd->detect_cycles(); if (cycles != nullptr) { cout << "cycles->size(): " << cycles->size() << endl; for (unsigned i = 0; i < case_d.size(); i++) { // print out the cycles if ((*cycles)[i]) cout << "Cyclic edge found: (" << case_d[i].first << ", " << case_d[i].second << ")" << endl; } cout << endl; // output a picture rs.push_back(new Rectangle(65,65+5,60,60+5)); rs.push_back(new Rectangle(65,65+5,30,30+5)); rs.push_back(new Rectangle(30,30+5,30,30+5)); rs.push_back(new Rectangle(30,30+5,60,60+5)); rs.push_back(new Rectangle(10,10+5,10,10+5)); assert(rs.size() == V); output_svg(rs, case_d, "cycle_detector_case_d.svg", false, true, cycles); for (unsigned i = 0; i < rs.size(); i++) { delete rs[i]; } rs.clear(); delete cycles; } else { cout << "No cycles found" << endl; } // create case E // case E is a reordering of case C cout << endl << "ENTERING CASE E" << endl; V = 14; case_e.push_back(Edge(0, 6)); case_e.push_back(Edge(0, 9)); case_e.push_back(Edge(1, 4)); case_e.push_back(Edge(3, 10)); case_e.push_back(Edge(4, 3)); case_e.push_back(Edge(5, 0)); case_e.push_back(Edge(6, 7)); case_e.push_back(Edge(7, 0)); case_e.push_back(Edge(7, 2)); case_e.push_back(Edge(7, 10)); case_e.push_back(Edge(8, 5)); case_e.push_back(Edge(9, 12)); case_e.push_back(Edge(9, 11)); case_e.push_back(Edge(9, 13)); case_e.push_back(Edge(10, 1)); case_e.push_back(Edge(10, 4)); case_e.push_back(Edge(12, 0)); case_e.push_back(Edge(11, 12)); // detect the cycles cd->mod_graph(V, &case_e); cycles = cd->detect_cycles(); if (cycles != nullptr) { cout << "cycles->size(): " << cycles->size() << endl; for (unsigned i = 0; i < case_e.size(); i++) { // print out the cycles if ((*cycles)[i]) cout << "Cyclic edge found: (" << case_e[i].first << ", " << case_e[i].second << ")" << endl; } cout << endl; // output a picture rs.push_back(new Rectangle(80,80+5,15,15+5)); // node 6 rs.push_back(new Rectangle(45,45+5,90,90+5)); // node 13 rs.push_back(new Rectangle(20,20+5,40,40+5)); // node 1 rs.push_back(new Rectangle(30,30+5,60,60+5)); // node 3 rs.push_back(new Rectangle(60,60+5,60,60+5)); // node 4 rs.push_back(new Rectangle(110,110+5,15,15+5)); // node 7 rs.push_back(new Rectangle(40,40+5,30,30+5)); // node 2 rs.push_back(new Rectangle(10,10+5,10,10+5)); // node 0 rs.push_back(new Rectangle(140,140+5,15,15+5)); // node 8 rs.push_back(new Rectangle(110,110+5,60,60+5)); // node 9 rs.push_back(new Rectangle(10,10+5,90,90+5)); // node 5 rs.push_back(new Rectangle(140,140+5,70,70+5)); // node 12 rs.push_back(new Rectangle(100,100+5,85,85+5)); // node 10 rs.push_back(new Rectangle(140,140+5,50,50+5)); // node 11 assert(rs.size() == V); output_svg(rs, case_e, "cycle_detector_case_e.svg", false, true, cycles); for(int i = 0; i < V; i++) { delete rs[i]; } rs.clear(); delete cycles; } // create case F // case F consists of the same graph with sinks cout << endl << "ENTERING CASE F" << endl; V = 3; case_f.push_back(Edge(0, 1)); case_f.push_back(Edge(0, 2)); case_f.push_back(Edge(1, 2)); // detect the cycles cd->mod_graph(V, &case_f); cycles = cd->detect_cycles(); if (cycles != nullptr) { // output a picture rs.push_back(new Rectangle(10,10+5,10,10+5)); rs.push_back(new Rectangle(40,40+5,30,30+5)); rs.push_back(new Rectangle(15,15+5,60,60+5)); assert(rs.size() == V); output_svg(rs, case_f, "cycle_detector_case_f.svg", false, true, cycles); for (unsigned i = 0; i < rs.size(); i++) { delete rs[i]; } rs.clear(); cout << "No cycles found" << endl; } // This tests the cycle detectors ability to cycle through a chain of cyclic ancestors cout << endl << "ENTERING CYCLIC ANCESTOR TEST" << endl; Node a(1), b(2), c(3), d(4), e(5), f(6); // set up the chain f.cyclicAncestor = &e; e.cyclicAncestor = &d; d.cyclicAncestor = &c; c.cyclicAncestor = &b; b.cyclicAncestor = &a; a.cyclicAncestor = &a; Node *ca = cd->get_highest_ca(&f); if (ca != nullptr) { cout << "Highest cyclic ancestor found at vertex(" << ca->id << ")" << endl; } // create case G // case G hows the ability to find nested cycles and to reassign cyclic ancestors cout << endl << "ENTERING CASE G" << endl; V = 7; case_g.push_back(Edge(0, 1)); case_g.push_back(Edge(1, 2)); case_g.push_back(Edge(2, 3)); case_g.push_back(Edge(3, 4)); case_g.push_back(Edge(4, 5)); case_g.push_back(Edge(5, 6)); case_g.push_back(Edge(6, 5)); case_g.push_back(Edge(5, 4)); case_g.push_back(Edge(4, 3)); case_g.push_back(Edge(3, 2)); case_g.push_back(Edge(2, 1)); case_g.push_back(Edge(1, 0)); case_g.push_back(Edge(0, 6)); // detect the cycles cd->mod_graph(V, &case_g); cycles = cd->detect_cycles(); if (cycles != nullptr) { cout << "cycles->size(): " << cycles->size() << endl; for (unsigned i = 0; i < case_g.size(); i++) { // print out the cycles if ((*cycles)[i]) cout << "Cyclic edge found: (" << case_g[i].first << ", " << case_g[i].second << ")" << endl; } cout << endl; // output a picture cout << "No picture generated" << endl; /*rs.push_back(new Rectangle(50,50+5,10,10+5)); rs.push_back(new Rectangle(50,50+5,30,30+5)); rs.push_back(new Rectangle(50,50+5,60,60+5)); rs.push_back(new Rectangle(10,10+5,70,70+5)); rs.push_back(new Rectangle(50,50+5,100,100+5)); rs.push_back(new Rectangle(10,10+5,40,40+5)); assert(rs.size() == V); output_svg(rs, case_a, "cycle_detector_case_g.svg", false, true, cycles); for (unsigned i = 0; i < rs.size(); i++) { delete rs[i]; } rs.clear();*/ delete cycles; } else { cout << "No cycles found" << endl; } // END TEST delete cd; return 0; }