experiments_synthetic_expand.py

from __future__ import division
from muturank import Muturank_new
from synthetic import SyntheticDataConverter
from metrics import evaluate
from dblp import dblp_loader
import networkx as nx
from itertools import combinations_with_replacement
import random
from tensor import TensorFact
import pickle
from collections import OrderedDict
import time
import json
from tabulate import tabulate
import datetime
import pprint


class Data(object):
    def __init__(self, comms, graphs, timeFrames, number_of_dynamic_communities, dynamic_truth=[]):
        self.comms = comms
        self.graphs = graphs
        self.timeFrames = timeFrames
        self.number_of_dynamic_communities = number_of_dynamic_communities
        self.dynamic_truth = dynamic_truth


def object_decoder(obj, num):
    if 'type' in obj[num] and obj[num]['type'] == 'hand':
        edges = {int(tf): [(edge[0], edge[1]) for edge in edges] for tf, edges in obj[num]['edges'].items()}
        graphs = {}
        for i, edges in edges.items():
            graphs[i] = nx.Graph(edges)
        comms = {int(tf): {int(id): com for id, com in coms.items()} for tf, coms in obj[num]['comms'].items()}
        dynamic_coms = {int(id): [str(node) for node in com] for id, com in obj[num]['dynamic_truth'].items()}
        return Data(comms, graphs, len(graphs), len(dynamic_coms), dynamic_coms)
    return obj


# def evaluate(results, ground_truth, method, name):
#     nmi = NMI(ground_truth, method.dynamic_coms, evaluation_type="sets").results
#     omega = Omega(ground_truth, method.dynamic_coms)
#     bcubed = Bcubed(ground_truth, method.dynamic_coms)
#     results["Method"].append(name)
#     results['NMI'].append(nmi['NMI<Max>'])
#     results['Omega'].append(omega.omega_score)
#     results['Bcubed-Precision'].append(bcubed.precision)
#     results['Bcubed-Recall'].append(bcubed.recall)
#     results['Bcubed-F1'].append(bcubed.fscore)
#     return results


def run_experiments(data, ground_truth, network_num):
    all_res = []
    # Timerank with one connection - default q
    mutu4 = Muturank_new(data.graphs, threshold=1e-6, alpha=0.85, beta=0.85, connection='one',
                         clusters=len(ground_truth), default_q=True)
    all_res.append(
        evaluate.get_results(ground_truth, mutu4.dynamic_coms, "Timerank with one connection - default q", mutu4.tfs,
                             eval="dynamic", duration=mutu4.duration))
    all_res.append(
        evaluate.get_results(ground_truth, mutu4.dynamic_coms, "Timerank with one connection - default q", mutu4.tfs,
                             eval="sets", duration=mutu4.duration))
    all_res.append(
        evaluate.get_results(ground_truth, mutu4.dynamic_coms, "Timerank with one connection - default q", mutu4.tfs,
                             eval="per_tf", duration=mutu4.duration))
    f = open(results_file, 'a')
    f.write(tabulate(all_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    # Timerank with all connections - default q
    mutu5 = Muturank_new(data.graphs, threshold=1e-6, alpha=0.85, beta=0.85, connection='all',
                         clusters=len(ground_truth), default_q=True)
    all_res.append(evaluate.get_results(ground_truth, mutu5.dynamic_coms, "Timerank with all connections - default q"
                                        , mutu5.tfs,
                                        eval="dynamic", duration=mutu5.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu5.dynamic_coms, "Timerank with all connections - default "
                                                                          "q", mutu5.tfs,
                                        eval="sets", duration=mutu5.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu5.dynamic_coms, "Timerank with all connections - default "
                                                                          "q", mutu5.tfs,
                                        eval="per_tf", duration=mutu5.duration))
    f = open(results_file, 'a')
    f.write(tabulate(all_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    # Timerank with next connection - default q
    mutu6 = Muturank_new(data.graphs, threshold=1e-6, alpha=0.85, beta=0.85, connection='next',
                         clusters=len(ground_truth), default_q=True)
    all_res.append(evaluate.get_results(ground_truth, mutu6.dynamic_coms, "Timerank with next connection - default q"
                                        , mutu6.tfs, eval="dynamic", duration=mutu6.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu6.dynamic_coms, "Timerank with next connection - default q",
                                        mutu6.tfs, eval="sets", duration=mutu6.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu6.dynamic_coms, "Timerank with next connection - default q",
                                        mutu6.tfs, eval="per_tf", duration=mutu6.duration))
    f = open(results_file, 'a')
    f.write(tabulate(all_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    # NNTF
    fact = TensorFact(data.graphs, num_of_coms=len(ground_truth), threshold=1e-4, seeds=10, overlap=False)
    all_res.append(evaluate.get_results(ground_truth, fact.dynamic_coms, "NNTF", mutu6.tfs, eval="dynamic",
                                        duration=fact.duration))
    all_res.append(evaluate.get_results(ground_truth, fact.dynamic_coms, "NNTF", mutu6.tfs, eval="sets",
                                        duration=fact.duration))
    all_res.append(evaluate.get_results(ground_truth, fact.dynamic_coms, "NNTF", mutu6.tfs, eval="per_tf",
                                        duration=fact.duration))
    f = open(results_file, 'a')
    f.write(tabulate(all_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    with open(results_file, 'a') as f:
        f.write("NNTF\n")
        f.write("Error: " + str(fact.error) + "Seed: " + str(fact.best_seed) + "\n")
        f.write("A\n")
        pprint.pprint(fact.A, stream=f, width=150)
        f.write("B\n")
        pprint.pprint(fact.B, stream=f, width=150)
        f.write("C\n")
        pprint.pprint(fact.C, stream=f, width=150)
        pprint.pprint(fact.dynamic_coms, stream=f, width=150)
    # GED
    import sys
    sys.path.insert(0, '../GED/')
    import preprocessing, Tracker
    start_time = time.time()
    from ged import GedWrite, ReadGEDResults
    ged_data = GedWrite(data)
    graphs = preprocessing.getGraphs(ged_data.fileName)
    tracker = Tracker.Tracker(graphs)
    tracker.compare_communities()
    # outfile = 'tmpfiles/ged_results.csv'
    outfile = './results/GED-events-handdrawn-' + str(network_num) + '.csv'
    with open(outfile, 'w')as f:
        for hypergraph in tracker.hypergraphs:
            hypergraph.calculateEvents(f)
    ged_time = str(datetime.timedelta(seconds=int(time.time() - start_time)))
    print("--- %s seconds ---" % (ged_time))
    ged = ReadGEDResults.ReadGEDResults(file_coms=ged_data.fileName, file_output=outfile)
    with open(results_file, 'a') as f:
        f.write("GED\n")
        pprint.pprint(ged.dynamic_coms, stream=f, width=150)
    all_res.append(
        evaluate.get_results(ground_truth, ged.dynamic_coms, "GED", mutu6.tfs, eval="dynamic", duration=ged_time))
    all_res.append(
        evaluate.get_results(ground_truth, ged.dynamic_coms, "GED", mutu6.tfs, eval="sets", duration=ged_time))
    f = open(results_file, 'a')
    f.write(tabulate(all_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    # all_res.append(evaluate.get_results(ground_truth, ged.dynamic_coms, "GED", mutu6.tfs, eval="per_tf"))
    # Run Timerank - One connection
    mutu1 = Muturank_new(data.graphs, threshold=1e-6, alpha=0.85, beta=0.85, connection='one',
                         clusters=len(ground_truth), default_q=False)
    all_res.append(evaluate.get_results(ground_truth, mutu1.dynamic_coms, "Timerank with one connection", mutu1.tfs,
                                        eval="dynamic", duration=mutu1.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu1.dynamic_coms, "Timerank with one connection", mutu1.tfs,
                                        eval="sets", duration=mutu1.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu1.dynamic_coms, "Timerank with one connection", mutu1.tfs,
                                        eval="per_tf", duration=mutu1.duration))
    f = open(results_file, 'a')
    f.write(tabulate(all_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    muturank_res = OrderedDict()
    muturank_res["tf/node"] = ['t' + str(tf) for tf in mutu1.tfs_list]
    for i, node in enumerate(mutu1.node_ids):
        muturank_res[node] = [mutu1.p_new[tf * len(mutu1.node_ids) + i] for tf in range(mutu1.tfs)]
    f = open(results_file, 'a')
    f.write("ONE CONNECTION\n")
    f.write(tabulate(muturank_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.write(tabulate(zip(['t' + str(tf) for tf in mutu1.tfs_list], mutu1.q_new), headers="keys",
                     tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()

    # Timerank with all connections
    mutu2 = Muturank_new(data.graphs, threshold=1e-6, alpha=0.85, beta=0.85, connection='all',
                         clusters=len(ground_truth), default_q=False)
    all_res.append(evaluate.get_results(ground_truth, mutu2.dynamic_coms, "Timerank with all connections", mutu2.tfs,
                                        eval="dynamic", duration=mutu2.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu2.dynamic_coms, "Timerank with all connections", mutu2.tfs,
                                        eval="sets", duration=mutu2.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu2.dynamic_coms, "Timerank with all connections", mutu2.tfs,
                                        eval="per_tf", duration=mutu2.duration))
    f = open(results_file, 'a')
    f.write(tabulate(all_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    muturank_res = OrderedDict()
    muturank_res["tf/node"] = ['t' + str(tf) for tf in mutu2.tfs_list]
    for i, node in enumerate(mutu2.node_ids):
        muturank_res[node] = [mutu2.p_new[tf * len(mutu2.node_ids) + i] for tf in range(mutu2.tfs)]
    f = open(results_file, 'a')
    f.write("ALL CONNECTIONS\n")
    f.write(tabulate(muturank_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.write(tabulate(zip(['t' + str(tf) for tf in mutu2.tfs_list], mutu2.q_new), headers="keys",
                     tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    # Timerank with next connection
    mutu3 = Muturank_new(data.graphs, threshold=1e-6, alpha=0.85, beta=0.85, connection='next',
                         clusters=len(ground_truth), default_q=False)
    all_res.append(evaluate.get_results(ground_truth, mutu3.dynamic_coms, "Timerank with next connection", mutu3.tfs,
                                        eval="dynamic", duration=mutu3.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu3.dynamic_coms, "Timerank with next connection", mutu3.tfs,
                                        eval="sets", duration=mutu3.duration))
    all_res.append(evaluate.get_results(ground_truth, mutu3.dynamic_coms, "Timerank with next connection", mutu3.tfs,
                                        eval="per_tf", duration=mutu3.duration))
    f = open(results_file, 'a')
    f.write(tabulate(all_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()
    muturank_res = OrderedDict()
    muturank_res["tf/node"] = ['t' + str(tf) for tf in mutu3.tfs_list]
    for i, node in enumerate(mutu3.node_ids):
        muturank_res[node] = [mutu3.p_new[tf * len(mutu3.node_ids) + i] for tf in range(mutu3.tfs)]
    f = open(results_file, 'a')
    f.write("NEXT CONNECTION\n")
    f.write(tabulate(muturank_res, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.write(tabulate(zip(['t' + str(tf) for tf in mutu3.tfs_list], mutu3.q_new), headers="keys",
                     tablefmt="fancy_grid").encode('utf8') + "\n")
    f.write("GROUND TRUTH\n")
    pprint.pprint(ground_truth, stream=f, width=150)
    f.write("ONE CONNECTION\n")
    pprint.pprint(mutu1.dynamic_coms, stream=f, width=150)
    f.write("ALL CONNECTIONS\n")
    pprint.pprint(mutu2.dynamic_coms, stream=f, width=150)
    f.write("NEXT CONNECTION\n")
    pprint.pprint(mutu3.dynamic_coms, stream=f, width=150)
    f.close()
    return all_res


if __name__ == "__main__":
    import sys

    if len(sys.argv) > 1:
        folder = sys.argv[1]
    else:
        folder = "expand_contract_data"
    from os.path import expanduser

    home = expanduser("~")
    path_full = home + "/Dropbox/Msc/thesis/data/synthetic_generator/data/" + folder
    results_file = "results_synthetic_" + path_full.split("/")[-1] + ".txt"
    sd = SyntheticDataConverter(path_full, remove_redundant_nodes=True)
    # nodes = sd.graphs[0].nodes()
    # # edges_1 = random.sample(list(combinations_with_replacement(nodes, 2)), 50)
    # # edges_2 = random.sample(list(combinations_with_replacement(nodes, 2)), 207)
    #  ---------------------------------
    # Dynamic Network Generator data (50 nodes/3 tfs)
    number_of_dynamic_communities = len(sd.graphs[0])
    data = Data(comms=sd.comms, graphs=sd.graphs, timeFrames=len(sd.graphs), number_of_dynamic_communities=len(
        sd.dynamic_truth), dynamic_truth=sd.dynamic_truth)
    #  ---------------------------------
    # Dynamic Network Generator data (50 nodes/3 tfs) - Same network everywhere except one tf
    # dict = {
    #     0: sd.graphs[0],
    #     1: sd.graphs[0],
    #     2: sd.graphs[2],
    #     3: sd.graphs[0],
    #     4: sd.graphs[0]
    # }
    # comms = {0: sd.comms[0], 1: sd.comms[0],2: sd.comms[2], 3: sd.comms[0],4: sd.comms[0]}
    # number_of_dynamic_communities = len(sd.comms[0])
    # data = Data(comms, dict, len(dict), len(sd.comms[0]))
    # ---------------------------------
    # dblp = dblp_loader("data/dblp/my_dblp_data.json", start_year=2000, end_year=2004, coms='comp')
    # number_of_dynamic_communities = len(dblp.dynamic_coms)
    # data = Data(dblp.communities, dblp.graphs, len(dblp.graphs), len(dblp.dynamic_coms))
    # ground_truth = dblp.dynamic_coms
    # ---------------------------------
    # from plot import PlotGraphs
    # PlotGraphs(data.graphs, len(data.graphs), 'expand-contract', 100)
    all_res = run_experiments(data, data.dynamic_truth, 'expand')
    results = OrderedDict()
    results["Method"] = []
    results['Eval'] = []
    results['NMI'] = []
    results['Omega'] = []
    results['Bcubed-Precision'] = []
    results['Bcubed-Recall'] = []
    results['Bcubed-F1'] = []
    results['Duration'] = []
    for res in all_res:
        for k, v in res.items():
            results[k].extend(v)
    f = open(results_file, 'a')
    f.write(tabulate(results, headers="keys", tablefmt="fancy_grid").encode('utf8') + "\n")
    f.close()