def solve_graph(graph, name):
"""
Runs a planarity test on a predefined graph.
Args:
graph (networkx.Graph): Input graph
name (str): The name of the graph
Returns:
planarity (bool): Planarity of the graph
"""
# graph_nodes = len(graph.nodes())
# graph_edges = len(graph.edges())
# FouldsRobinsonPlanarity.find_planarity(G)
# TarjanHopcroftPlanarity.find_planarity(graph)
planar, bad_graph = KuratowskiPlanarity.find_planarity(graph)
print "Graph %s is planar: %s" % (
name,
planar,
)
GraphUtils.draw_graph(graph, name, bad_graph)
return planar
def testPlanar(self):
# Generate K(4) graph
p_graph = GraphGenerator.make_planar_graph()
# Test graph
planar, bad_graph = KuratowskiPlanarity.find_planarity(p_graph)
GraphUtils.draw_graph(p_graph, "planar_test", bad_graph)
# print "Test on planar graph:", 'PASS' if planar else 'FAIL'
self.assertTrue(planar) # True means graph is planar
def testK5(self):
# Generate K(5) graph
k5 = GraphGenerator.make_k5_graph()
# Test graph
planar, bad_graph = KuratowskiPlanarity.find_planarity(k5)
GraphUtils.draw_graph(k5, "K5", bad_graph)
# print "Test on K(5):", 'FAIL' if planar else 'PASS'
self.assertFalse(planar) # False means K(5) subgraph was found
def testK33(self):
# Generate K(3, 3) graph
k33 = GraphGenerator.make_k33_graph()
# Test graph
planar, bad_graph = KuratowskiPlanarity.find_planarity(k33)
GraphUtils.draw_graph(k33, "K33", bad_graph)
# print "Test on K(3, 3):", 'FAIL' if planar else 'PASS'
self.assertFalse(planar) # False means K(3, 3) subgraph was found
def testPlanar(self):
# Generate K(4) graph
p_graph = GraphGenerator.make_planar_graph()
# Test graph
planar, bad_graph = KuratowskiPlanarity.find_planarity(p_graph)
GraphUtils.draw_graph(p_graph, "planar_test", bad_graph)
# print "Test on planar graph:", 'PASS' if planar else 'FAIL'
self.assertTrue(planar) # True means graph is planar
def testK5(self):
# Generate K(5) graph
k5 = GraphGenerator.make_k5_graph()
# Test graph
planar, bad_graph = KuratowskiPlanarity.find_planarity(k5)
GraphUtils.draw_graph(k5, "K5", bad_graph)
# print "Test on K(5):", 'FAIL' if planar else 'PASS'
self.assertFalse(planar) # False means K(5) subgraph was found
def testK33(self):
# Generate K(3, 3) graph
k33 = GraphGenerator.make_k33_graph()
# Test graph
planar, bad_graph = KuratowskiPlanarity.find_planarity(k33)
GraphUtils.draw_graph(k33, "K33", bad_graph)
# print "Test on K(3, 3):", 'FAIL' if planar else 'PASS'
self.assertFalse(planar) # False means K(3, 3) subgraph was found
