def printRes(G, resG, expectedG, layers=[]): fig = plt.figure() n = len(G) ### Parameters if (n < 50): withLabel = True nodeSize = 300 else: withLabel = False nodeSize = 0 if expectedG is None: resFig = fig.add_subplot(111, aspect='equal') else: resFig = fig.add_subplot(121, aspect='equal') if nx.is_connected(resG): resEPL = ev.getEPL(G, resG) resMax = ev.getMaxDegree(resG) resFig.title.set_text("result (EPL = " + str(resEPL) + ", max degree = " + str(resMax) + ")") # nx.draw_circular(resG, with_labels=withLabel, node_size=nodeSize) pos = nx.circular_layout(resG) nx.draw_networkx_nodes(resG, pos) nx.draw_networkx_labels(resG, pos) nx.draw_networkx_edges(resG, pos, edge_color='k') for layer in layers: subG = nx.from_numpy_matrix(layer) elist = nx.to_edgelist(subG) nx.draw_networkx_edges(resG, pos, edgelist=elist, edge_color=(rd.random(), rd.random(), rd.random()), width=5 * rd.random()) if expectedG is None: resDegrees = ev.getDegrees(resG) print("final degrees : " + str(resDegrees)) else: expectedEPL = ev.getEPL(G, expectedG) expectedFig = fig.add_subplot(122, aspect='equal') expectedFig.title.set_text("expected (EPL = " + str(expectedEPL) + ")") nx.draw_circular(expectedG, with_labels=withLabel, node_size=nodeSize) plt.plot() plt.show()
def launch(nodes, highOutSubsets, highInSubsets, i, j): G = severalWheels(nodes, highOutSubsets, highInSubsets) res = sp.sparseToBND(G) N, _ = res[0], res[1] EPL = ev.getEPL(G, N) _max = ev.getMaxDegree(N) results.append([i, j, EPL, _max]) if index[0] > checkpoint[0]: print(str(checkpointIndex[0]) + '%') checkpointIndex[0] += 1 checkpoint[0] += step index[0] += 1
def launch(nodes, highSubsets, i): G = superStars(k, m, highSubsets, kernelSubsets) res = sp.sparseToBND(G) N, layers = res[0], res[1] if not nx.is_connected(N): subgraphs = list(nx.connected_component_subgraphs(N)) for H in subgraphs: nx.draw_networkx(H) plt.show() raise NameError('The result graph is not connected') EPL = ev.getEPL(G, N) _max = ev.getMaxDegree(N) results.append([i, EPL, _max]) if index[0] > checkpoint[0]: print(str(checkpointIndex[0]) + '%') checkpointIndex[0] += 1 checkpoint[0] += step index[0]+=1
dr.printInput(G) res = sp.sparseToBND(G) N, layers = res[0], res[1] dr.printRes(G, N, None, layers) ### Several test on random graphs if choice == 1: N, n = 100000, 20 results = [] inputs = [] for i in tqdm(range(N)): G = randomGraph(n) edges = str(G.edges) avgDegree = ev.getAverageDegree(G) n = len(G) res = sp.sparseToBND(G) N, layers = res[0], res[1] if nx.is_connected(N): EPL = ev.getEPL(G, N) _max = ev.getMaxDegree(N) results.append([EPL, _max, 12 * avgDegree, edges]) headers = ['EPL', 'max degree', 'theorical max degree', 'edges'] file = 'results/' + 'random_graphs.csv' ex.exportToCSV(file, headers, results)
def update(num): if num < 3*m: if num % 3 == 0: left.clear() index = num//3 edge = edges[index] rerouter = rerouters[index] left.set_title(f"I - Rerouting of the edge : ({edge[0]}, {edge[1]}) -> helper : {rerouter}") DrawInput.remove_edge(edge[0], edge[1]) nx.draw_circular(DrawInput, ax=left, arrowstyle='->', arrowsize=10, with_labels=True, node_color=colors) for i in range(len(middles)): middle = middles[i] middle.clear() subGraph = subGraphs[i] if i == edge[0] or i == edge[1]: nx.draw_circular(subGraph, ax=middle, edge_color=colors[i], with_labels=True, node_color=colors) else: nx.draw_circular(subGraph, ax=middle, edge_color="#d3d3d3", with_labels=True, node_color="#d3d3d3") elif num % 3 == 1: index = num//3 edge = edges[index] node = edge[0] middle = middles[node] middle.clear() rerouter = rerouters[index] subGraph = subGraphs[node] subGraph.add_edge(node, rerouter) nx.draw_circular(subGraph, ax=middle, edge_color=colors[node], with_labels=True, node_color=colors) elif num % 3 == 2: index = num//3 edge = edges[index] node = edge[1] middle = middles[node] middle.clear() rerouter = rerouters[index] subGraph = subGraphs[node] subGraph.add_edge(rerouter, node) nx.draw_circular(subGraph, ax=middle, edge_color=colors[node], with_labels=True, node_color=colors) if num == 3*m: for i in range(len(middles)): middle = middles[i] middle.clear() subGraph = subGraphs[i] nx.draw_circular(subGraph, ax=middle, edge_color="#d3d3d3", with_labels=True, node_color="#d3d3d3") if num >= 3*m and num < 3*m + n: index = num - 3*m left.set_title(f"II - Formation of the MTs from the node {index}") middle = middles[index] middle.clear() nx.draw_circular(finalSubGraphs[index], ax=middle, edge_color=colors[index], with_labels=True, node_color=colors) if num == 3*m + n: EPL = ev.getEPL(_input, result) maxDegree = ev.getMaxDegree(result) left.clear() left.set_title(f"III - Combination of all the MTs (EPL: {EPL}, max degree: {maxDegree}), avg degree: {avgDegree}") nx.draw_circular(result, ax=left, with_labels=True, node_color=colors)
inDegrees = [7 for i in range(75)] + [99 for i in range(25)] outDegrees = [7 for i in range(60)] + [99 for i in range(25) ] + [7 for i in range(15)] results = [] i = 0 for i in tqdm(range(N)): input = randomGraph2(inDegrees, outDegrees) res = sp.sparseToBND2(input) result = res[0] avgDegree = ev.getAverageDegree(input) initialMaxDegree = ev.getMaxDegree(input) maxDegree = ev.getMaxDegree(result) / 2 #because undirected EPL = ev.getEPL(input, result) firstDegreeBound = 3 * avgDegree secondDegreeBound = firstDegreeBound + 6 line = [ str(n), str(m), str(avgDegree), str(initialMaxDegree), str(maxDegree), str(EPL), str(firstDegreeBound), str(secondDegreeBound) ] results.append(line)