""" This file is note meant to be run, it's just a collection of functions that are used in the other files. It's just a way to keep the code clean and organized. """ import os import gzip import wget import gdown import shutil import random import itertools import numpy as np import pandas as pd import tqdm as tqdm import networkx as nx import multiprocessing import plotly.graph_objects as go from itertools import combinations from pyvis.network import Network from multiprocessing import Pool from collections import Counter from subprocess import run from typing import Literal from queue import Empty SCRIPT_DIR = os.path.dirname(os.path.abspath(__file__)) DATA_DIR = os.path.join(SCRIPT_DIR, "data") # ------------------------------------------------------------------------# def download_datasets(): """ Download the datasets from the web and unzip them. The datasets are downloaded from the SNAP website and from a Google Drive folder. Parameters ---------- None Returns ------- None Notes ----- The datasets are downloaded in the "data" folder. If the folder doesn't exist, it will be created. If the dataset is already downloaded, it will be skipped. The files are renamed to make them more readable. """ dict = { "brightkite": ["https://snap.stanford.edu/data/loc-brightkite_edges.txt.gz", "https://snap.stanford.edu/data/loc-brightkite_totalCheckins.txt.gz"], "gowalla": ["https://snap.stanford.edu/data/loc-gowalla_edges.txt.gz", "https://snap.stanford.edu/data/loc-gowalla_totalCheckins.txt.gz"], "foursquare": ["https://drive.google.com/file/d/1PNk3zY8NjLcDiAbzjABzY5FiPAFHq6T8/view?usp=sharing"] } if not os.path.exists(DATA_DIR): os.mkdir(DATA_DIR) print("Created data folder") for folder in dict.keys(): if not os.path.exists(os.path.join(DATA_DIR, folder)): os.mkdir(os.path.join(DATA_DIR, folder)) print("Created {} folder".format(folder)) ## DOWNLOADING ## for folder in dict.keys(): for url in dict[folder]: if folder == "foursquare": if not os.path.exists(os.path.join(DATA_DIR, folder, "foursquare_full.zip")): output = os.path.join(DATA_DIR, folder, "foursquare_full.zip") gdown.download(url, output, quiet=False, fuzzy=True) else : print("{} already downloaded".format(url)) else: if not os.path.exists(os.path.join(DATA_DIR, folder, url.split("/")[-1])): print("Downloading {}...".format(url)) wget.download(url, os.path.join(DATA_DIR, folder)) else : print("{} already downloaded".format(url)) ## UNZIPPING ## for folder in dict.keys(): for file in os.listdir(os.path.join(DATA_DIR, folder)): if file.endswith(".gz"): print("Unzipping {}...".format(file)) # os.system("gunzip {}".format(os.path.join(DATA_DIR, folder, file))) gzip_file_path = os.path.join(DATA_DIR, folder, file) with gzip.open(gzip_file_path, 'rb') as f_in: with open(gzip_file_path[:-len(".gz")], 'wb') as f_out: shutil.copyfileobj(f_in, f_out) elif file.endswith(".zip"): print("Unzipping {}...".format(file)) zip_file_path = os.path.join(DATA_DIR, folder, file) zip_output_dir = os.path.join(DATA_DIR, folder) if os.name == 'nt': # Not tested! Require Windows 10+ and Powershell os.system(f'powershell -command "Expand-Archive -Force \'{zip_file_path}\' \'{zip_output_dir}\'"') else: run(["unzip", "-o", zip_file_path, "-d", zip_output_dir]) os.remove(zip_file_path) ## FOURSQUARE CLEANING ## for file in os.listdir(os.path.join(DATA_DIR, "foursquare", "dataset_WWW2019")): if file.endswith(".txt"): os.rename(os.path.join(DATA_DIR, "foursquare", "dataset_WWW2019", file), os.path.join(DATA_DIR, "foursquare", file)) for file in ["dataset_WWW_friendship_old.txt", "dataset_WWW_readme.txt", "raw_Checkins_anonymized.txt"]: os.remove(os.path.join(DATA_DIR, "foursquare", file)) shutil.rmtree(os.path.join(DATA_DIR, "foursquare", "dataset_WWW2019")) shutil.rmtree(os.path.join(DATA_DIR, "foursquare", "__MACOSX")) os.rename(os.path.join(DATA_DIR, "foursquare", "dataset_WWW_friendship_new.txt"), os.path.join(DATA_DIR, "foursquare", "foursquare_friends_edges.txt")) os.rename(os.path.join(DATA_DIR, "foursquare", "dataset_WWW_Checkins_anonymized.txt"), os.path.join(DATA_DIR, "foursquare", "foursquare_checkins_full.txt")) ## BRIGHTKITE CLEANING ## os.rename(os.path.join(DATA_DIR, "brightkite", "loc-brightkite_totalCheckins.txt"), os.path.join(DATA_DIR, "brightkite", "brightkite_checkins_full.txt")) os.rename(os.path.join(DATA_DIR, "brightkite", "loc-brightkite_edges.txt"), os.path.join(DATA_DIR, "brightkite", "brightkite_friends_edges.txt")) ## GOWALLA CLEANING ## os.rename(os.path.join(DATA_DIR, "gowalla", "loc-gowalla_totalCheckins.txt"), os.path.join(DATA_DIR, "gowalla", "gowalla_checkins_full.txt")) os.rename(os.path.join(DATA_DIR, "gowalla", "loc-gowalla_edges.txt"), os.path.join(DATA_DIR, "gowalla", "gowalla_friends_edges.txt")) # ------------------------------------------------------------------------# def create_graph_from_checkins(dataset: Literal['brightkite', 'gowalla', 'foursquareEU', 'foursquareIT'], create_file = True) -> nx.Graph: """ Create a graph from the checkins of the dataset. The graph is undirected and the nodes are the users and the edges are the checkins in common. Parameters ---------- `dataset` : Literal['brightkite', 'gowalla', 'foursquare'] The dataset to use. `create_file` : bool, optional If True, the graph is saved in a file, by default True Returns ------- `G` : networkx.Graph Raises ------ ValueError If the dataset is not valid. """ if dataset not in ['brightkite', 'gowalla', 'foursquare']: raise ValueError("Dataset not valid. Please choose between brightkite, gowalla, foursquare") file = os.path.join(DATA_DIR, dataset, dataset + "_checkins.txt") print("\nCreating the graph for the dataset {}...".format(dataset)) df = pd.read_csv(file, sep="\t", header=None, names=["user_id", "venue_id"], engine='pyarrow') G = nx.Graph() venues_users = df.groupby("venue_id")["user_id"].apply(set) for users in tqdm.tqdm(venues_users): for user1, user2 in combinations(users, 2): G.add_edge(user1, user2) # path to the file where we want to save the graph edges_path = os.path.join(DATA_DIR, dataset , dataset + "_checkins_edges.tsv") print("Done! The graph has {} edges".format(G.number_of_edges()), " and {} nodes".format(G.number_of_nodes())) # delete from memory the dataframe del df if create_file: # save the graph in a file nx.write_edgelist(G, edges_path, data=True, delimiter="\t", encoding="utf-8") return G # ------------------------------------------------------------------------# def create_friendships_graph(dataset: Literal['brightkite', 'gowalla', 'foursquareEU', 'foursquareIT']) -> nx.Graph: """ Create the graph of friendships for the dataset brightkite, gowalla or foursquare. The graph is saved in a file. Parameters ---------- `dataset` : str The dataset for which we want to create the graph of friendships. Returns ------- `G` : networkx.Graph The graph of friendships. Notes ----- Since we are taking sub-samples of each check-ins dataset, we are also taking sub-samples of the friendship graph. A user is included in the friendship graph if he has at least one check-in in the sub-sample. """ if dataset not in ["brightkite", "gowalla", "foursquare"]: raise ValueError("The dataset must be brightkite, gowalla or foursquare") file = os.path.join(DATA_DIR, dataset, dataset + "_friends_edges.txt") # read the file with the edges of the friendship graph and get the unique users df_friends_all = pd.read_csv(file, sep="\t", header=None, names=["node1", "node2"], engine='pyarrow') unique_friends = set(df_friends_all["node1"].unique()).union(set(df_friends_all["node2"].unique())) # read the file with the edges of the check-ins graph and get the unique users df_checkins = pd.read_csv(os.path.join(DATA_DIR, dataset, dataset + "_checkins_edges.tsv"), sep="\t", header=None, names=["node1", "node2"]) unique_checkins = set(df_checkins["node1"].unique()).union(set(df_checkins["node2"].unique())) # get the intersection of the two sets and filter the friendship graph unique_users = unique_friends.intersection(unique_checkins) df = df_friends_all[df_friends_all["node1"].isin(unique_users) & df_friends_all["node2"].isin(unique_users)] df.to_csv(os.path.join(DATA_DIR, dataset, dataset + "_friends_edges_filtered.tsv"), sep="\t", header=False, index=False) G = nx.from_pandas_edgelist(df, "node1", "node2", create_using=nx.Graph()) del df_friends_all, df_checkins, df # delete from memory the dataframes return G # ------------------------------------------------------------------------# def degree_distribution(G: nx.Graph, log: bool = True, save: bool = False) -> None: """ This function takes in input a networkx graph object and plots the degree distribution of the graph. Parameters ---------- `G` : networkx graph object The graph object `log` : bool, optional If True, the plot will be in log-log scale, by default True `save` : bool, optional If True, the plot will be saved in the folder "plots", by default False Returns ------- None Notes ----- Due to the characteristics of datasets, not using a log log scale will lead to a un-useful plot. Even if using a log scales alters the power-law distribution, it is still clearly visible and distinguishable from a poisson distribution (witch is what we are interested in in this case) """ degrees = [G.degree(n) for n in G.nodes()] degreeCount = Counter(degrees) fig = go.Figure() fig.add_trace(go.Bar(x=list(degreeCount.keys()), y=list(degreeCount.values()), name='Degree Distribution')) if log: fig.update_layout( title='Degree Distribution (log-log scale) of {}' .format(G.name), xaxis_title='Degree', yaxis_title='Number of Nodes', xaxis_type='log', yaxis_type='log', width=800, height=600, template='plotly_white' ) else: fig.update_layout( title='Degree Distribution of {}' .format(G.name), xaxis_title='Degree', yaxis_title='Number of Nodes', width=800, height=600, template='plotly_white' ) fig.show() if save: fig.write_image("plots/degree_distribution_{}.png".format(G.name)) # ------------------------------------------------------------------------# def chunks(l, n): """ Auxiliary function to divide a list of nodes `l` in `n` chunks Parameters ---------- `l` : list List of nodes `n` : int Number of chunks """ l_c = iter(l) while 1: x = tuple(itertools.islice(l_c, n)) if not x: return yield x # ------------------------------------------------------------------------# def betweenness_centrality_parallel(G, processes=None, k =None) -> dict: """ Compute the betweenness centrality for nodes in a graph using multiprocessing. Parameters ---------- G : graph A networkx graph processes : int, optional The number of processes to use for computation. If `None`, then it sets processes = 1 k : int, optional Percent of nodes to sample. If `None`, then all nodes are used. seed : int, optional Seed for random number generator (default=None). Returns ------- dict Notes ----- Do not use more then 6 process for big graphs, otherwise the memory will be full. Do it only if you have more at least 32 GB of RAM. For small graphs, you can use more processes. """ # if process is None or 1, run the standard algorithm with one process if processes is None or processes == 1: print("\tRunning the networkx approximated algorithm with just one process") G_copy = G.copy() sample = int((k)*G_copy.number_of_nodes()) print("\tNumber of nodes after removing {} % of nodes: {}" .format((k)*100, G_copy.number_of_nodes())) return np.mean(nx.betweenness_centrality(G, k=sample, seed=42).values()) if processes > os.cpu_count(): raise ValueError("The number of processes must be less than the number of cores in the system.") if k is not None: if (k < 0 or k > 1): raise ValueError("k must be between 0 and 1.") else: G_copy = G.copy() G_copy.remove_nodes_from(random.sample(G_copy.nodes(), int((k)*G_copy.number_of_nodes()))) print("\tNumber of nodes after removing {}% of nodes: {}" .format((k)*100, G_copy.number_of_nodes())) print("\tNumber of edges after removing {}% of nodes: {}" .format((k)*100, G_copy.number_of_edges())) if k is None: G_copy = G.copy() p = Pool(processes=processes) node_divisor = len(p._pool) * 4 node_chunks = list(chunks(G_copy.nodes(), G_copy.order() // node_divisor)) num_chunks = len(node_chunks) bt_sc = p.starmap( nx.betweenness_centrality_subset, zip( [G_copy] * num_chunks, # this returns a list of Gs node_chunks, [list(G_copy)] * num_chunks, # this returns a list of lists of nodes [True] * num_chunks, [None] * num_chunks, ), ) # Reduce the partial solutions bt_c = bt_sc[0] for bt in bt_sc[1:]: for n in bt: bt_c[n] += bt[n] return bt_c # ------------------------------------------------------------------------# def average_shortest_path(G: nx.Graph, k=None) -> float: """ This function takes in input a networkx graph and returns the average shortest path length of the graph. This works also for disconnected graphs. Parameters ---------- `G` : networkx graph The graph to compute the average shortest path length of. `k` : float percentage of nodes to remove from the graph. If `k` is None, the average shortest path length of each connected component is computed using all the nodes of the connected component. Returns ------- float The average shortest path length of the graph. Raises ------ ValueError If `k` is not between 0 and 1 """ if k is not None and (k < 0 or k > 1): raise ValueError("k must be between 0 and 1") elif k is None: G_copy = G.copy() connected_components = list(nx.connected_components(G)) else: G_copy = G.copy() # remove the k% of nodes from G G_copy.remove_nodes_from(random.sample(G_copy.nodes(), int((k)*G_copy.number_of_nodes()))) print("\tNumber of nodes after removing {}% of nodes: {}" .format((k)*100, G_copy.number_of_nodes())) print("\tNumber of edges after removing {}% of nodes: {}" .format((k)*100, G_copy.number_of_edges())) tmp = 0 connected_components = list(nx.connected_components(G_copy)) # remove all the connected components with less than 10 nodes connected_components = [c for c in connected_components if len(c) > 10] print("\tNumber of connected components with more then 10 nodes: {}" .format(len(connected_components)), "\r") for C in (G_copy.subgraph(c).copy() for c in connected_components): print("\tComputing average shortest path length of connected component with {} nodes and {} edges" .format(C.number_of_nodes(), C.number_of_edges()), "\r", end="") tmp += nx.average_shortest_path_length(C) return np.mean(tmp) # ------------------------------------------------------------------------# def average_clustering_coefficient(G: nx.Graph, k=None) -> float: """ This function takes in input a networkx graph and returns the average clustering coefficient of the graph. This works also for disconnected graphs. Parameters ---------- `G` : networkx graph The graph to compute the average clustering coefficient of. `k` : int percentage of nodes to remove from the graph. If `k` is None, the average clustering coefficient of each connected component is computed using all the nodes of the connected component. Returns ------- float The average clustering coefficient of the graph. Raises ------ ValueError If `k` is not between 0 and 1 """ if k is not None and (k < 0 or k > 1): raise ValueError("k must be between 0 and 1") elif k is None: return nx.average_clustering(G) else: G_copy = G.copy() G_copy.remove_nodes_from(random.sample(list(G_copy.nodes()), int((k)*G_copy.number_of_nodes()))) print("\tNumber of nodes after removing {}% of nodes: {}" .format((k)*100, G_copy.number_of_nodes())) return nx.average_clustering(G_copy) def generalized_average_clustering_coefficient(G: nx.Graph) -> float: """ Generalized definition of the average clustering coefficient of a graph. It better applies to small world networks and it's way more efficient than the average_clustering_coefficient function with the standard definition of the clustering coefficient. Parameters ---------- `G` : networkx graph The graph to compute the generalized average clustering coefficient of. Returns ------- float The generalized average clustering coefficient of the graph. """ C = 0 for node in G.nodes(): k = G.degree(node) C += (3*(k-1))/(2*(2*k - 1)) return C/G.number_of_nodes() # ------------------------------------------------------------------------# def create_random_graphs(G: nx.Graph, model = None, save = True) -> nx.Graph: """Create a random graphs with about the same number of nodes and edges of the original graph. Parameters ---------- `G` : nx.Graph The original graph. `model` : str The model to use to generate the random graphs. It can be one of the following: "erdos", "watts_strogatz" `save`: bool If True, the random graph is saved in the folder data/random/model Returns ------- `G_random` : nx.Graph """ if model is None: model = "erdos_renyi" if model == "erdos_renyi": G_random = nx.erdos_renyi_graph(G.number_of_nodes(), nx.density(G)) print("Creating a random graph with the Erdos-Renyi model {}" .format(G.name)) # print("Number of edges in the original graph: {}" .format(G.number_of_edges())) # print("Number of edges in the random graph: {}" .format(G_random.number_of_edges())) G_random.name = G.name + " Erdos-Renyi" if save: # check if the folder exists, otherwise create it if not os.path.exists(os.path.join(DATA_DIR, 'random', 'erdos')): os.makedirs(os.path.join(DATA_DIR, 'random', 'erdos')) nx.write_gpickle(G_random, os.path.join(DATA_DIR, 'random', 'erdos', "erdos_" + str(G.number_of_nodes()) + "_" + str(G_random.number_of_edges()) + ".gpickle")) print("\tThe file graph has been saved in the folder data/random/erdos with the syntax erdos_n_nodes_n_edges.gpickle") return G_random elif model == "watts_strogatz": p = G.number_of_edges() / (G.number_of_nodes()) avg_degree = int(np.mean([d for n, d in G.degree()])) G_random = nx.watts_strogatz_graph(G.number_of_nodes(), avg_degree, p) # print("Number of edges in the original graph: {}" .format(G.number_of_edges())) # print("Number of edges in the random graph: {}" .format(G_random.number_of_edges())) G_random.name = G.name + " Watts-Strogatz" if save: # check if the folder exists, otherwise create it if not os.path.exists(os.path.join(DATA_DIR, 'random', 'watts_strogatz')): os.makedirs(os.path.join(DATA_DIR, 'random', 'watts_strogatz')) nx.write_gpickle(G_random, os.path.join(DATA_DIR, 'random', 'watts_strogatz', "watts_strogatz_" + str(G.number_of_nodes()) + "_" + str(G_random.number_of_edges()) + ".gpickle")) print("\tThe file graph has been saved in the folder data/random/watts_strogatz with the syntax watts_strogatz_n_nodes_n_edges.gpickle") return G_random # ------------------------------------------------------------------------# def visualize_graphs(G: nx.Graph, k: float, connected = True): """ Function to visualize the graph in a HTML page using pyvis Parameters ---------- `G`: nx.Graph The graph to visualize `k`: float The percentage of nodes to remove from the graph. Default is None, in which case it will be chosen such that there are about 1000 nodes in the sampled graph. I strongly suggest to use the default value, other wise the visualization will be very slow. `connected`: bool If True, we will consider only the largest connected component of the graph Returns ------- `html file` The html file containing the visualization of the graph Notes: ------ This is of course an approximation, it's nice to have an idea of the graph, but it's not a good idea trying to understand the graph in details from this sampled visualization. """ if k is None: if len(G.nodes) > 1500: k = 1 - 1500/len(G.nodes) else: k = 0 # remove a percentage of the nodes nodes_to_remove = np.random.choice(list(G.nodes), size=int(k*len(G.nodes)), replace=False) G.remove_nodes_from(nodes_to_remove) if connected: # take only the largest connected component connected_components = list(nx.connected_components(G)) largest_connected_component = max(connected_components, key=len) G = G.subgraph(largest_connected_component) # create a networkx graph net = net = Network(directed=False, bgcolor='#1e1f29', font_color='white') # for some reasons, if I put % values, the graph is not displayed correctly. So I use pixels, sorry non FHD users net.width = '1920px' net.height = '1080px' # add nodes and edges net.add_nodes(list(G.nodes)) net.add_edges(list(G.edges)) # set the physics layout of the network net.set_options(""" var options = { "edges": { "color": { "inherit": true }, "smooth": false }, "physics": { "repulsion": { "centralGravity": 0.25, "nodeDistance": 500, "damping": 0.67 }, "maxVelocity": 48, "minVelocity": 0.39, "solver": "repulsion" } } """) name = G.name.replace(" ", "_").lower() if not os.path.exists("html_graphs"): os.mkdir("html_graphs") # save the graph in a html file net.show("html_graphs/{}.html".format(name)) print("The graph has been saved in the folder html_graphs with the name {}.html" .format(name)) # ------------------------------------------------------------------------# def random_sample(graph: nx.Graph, k: float) -> nx.Graph: """ Function to take a random sample of a graph Parameters ---------- `graph`: nx.Graph The graph to sample `k`: float The percentage of nodes to remove from the graph Returns ------- `G`: nx.Graph """ if not 0 <= k <= 1: raise ValueError("Percentage of nodes needs to be between 0 and 1") nodes = list(graph.nodes()) nodes_sample = np.random.choice(nodes, size=int((1-k)*len(nodes)), replace=False) G = graph.subgraph(nodes_sample) if not nx.is_connected(G): print("Graph is not connected. Taking the largest connected component") connected = max(nx.connected_components(G), key=len) G_connected = graph.subgraph(connected) print("Number of nodes in the sampled graph: ", G.number_of_nodes()) print("Number of edges in the sampled graph: ", G.number_of_edges()) return G_connected # ------------------------------------------------------------------------# def omega_sampled(G: nx.Graph, k: float, niter: int, nrand: int) -> float: """ Function to compute the omega index of a graph Parameters ---------- `G`: nx.Graph The graph to compute the omega index `k`: float The percentage of nodes to sample from the graph. `niter`: int Approximate number of rewiring per edge to compute the equivalent random graph. `nrand`: int Number of random graphs generated to compute the maximal clustering coefficient (Cr) and average shortest path length (Lr). Returns ------- `omega`: float The omega index of the graph """ # sample the graph G_sampled = random_sample(G, k) # compute the omega index omega = nx.omega(G_sampled, nrand, niter) return omega # ------------------------------------------------------------------------# def parallel_omega(G: nx.Graph, k: float, nrand: int = 6, niter: int = 6, n_processes: int = None, seed: int = 42) -> float: """ function to compute the omega index of a graph in parallel. This is a much faster approach then the standard omega function. It parallelizes the computation of the random graphs and lattice networks. Parameters ---------- `G`: nx.Graph The graph to compute the omega index `k`: float The percentage of nodes to sample from the graph. `niter`: int Approximate number of rewiring per edge to compute the equivalent random graph. Default is 6. `nrand`: int Number of random graphs generated to compute the maximal clustering coefficient (Cr) and average shortest path length (Lr). Default is 6 `n_processes`: int Number of processes to use. Default is the number of cores of the machine. `seed`: int The seed to use to generate the random graphs. Default is 42. Returns ------- `omega`: float Notes ----- This is just a notebook version of the program omega_parallel_server.py that you can find in the repository. This is supposed to be used just fo testing on small graphs. """ if n_processes is None: n_processes = multiprocessing.cpu_count() if n_processes > nrand: n_processes = nrand random.seed(seed) if not nx.is_connected(G): G = G.subgraph(max(nx.connected_components(G), key=len)) if len(G) == 1: return 0 # sample the graph G = random_sample(G, k) def worker(queue_seeds, queue_results): # worker function to be used in parallel while True: try: seed = queue_seeds.get(False) except Empty: break random_graph = nx.random_reference(G, niter, seed=seed) lattice_graph = nx.lattice_reference(G, niter, seed=seed) random_shortest_path = nx.average_shortest_path_length(random_graph) lattice_clustering = nx.average_clustering(lattice_graph) queue_results.put((random_shortest_path, lattice_clustering)) manager = multiprocessing.Manager() # manager to share the queue queue_seeds = manager.Queue() # queue to give the seeds to the processes queue_results = manager.Queue() # queue to share the results processes = [multiprocessing.Process(target=worker, args=(queue_seeds, queue_results)) for _ in range(n_processes)] # processes to be used for i in range(nrand): # put the tasks in the queue queue_seeds.put(i + seed) for process in processes: # start the processes process.start() for process in processes: # wait for the processes to finish process.join() # collect the results shortest_paths = [] clustering_coeffs = [] while not queue_results.empty(): random_shortest_path, lattice_clustering = queue_results.get() # get the results from the queue shortest_paths.append(random_shortest_path) clustering_coeffs.append(lattice_clustering) L = nx.average_shortest_path_length(G) C = nx.average_clustering(G) omega = (np.mean(shortest_paths) / L) - (C / np.mean(clustering_coeffs)) return omega