def print_number_of_traids_participated_by_random_node(G, GName):
TriadV = snap.TIntTrV()
snap.GetTriads(G, TriadV)
random_traid_node_index = snap.TInt.GetRnd(len(TriadV))
counter = 0
for triple in TriadV:
if counter == random_traid_node_index:
print "Number of traids of random node {0} participates in {1}: {2}".format(
triple.Val1(), GName[:-10], triple.Val2())
break
counter = counter + 1
number_of_edges_in_traids = snap.GetTriadEdges(G)
print "Number of edges that participate in at least one triad in {0}: {1}".format(
GName[:-10], number_of_edges_in_traids)
def print_connectivity_clustering(G):
"""
Prints the average clustering coefficient, number of triads in subgraph G
Also prints clustering coefficient and number of triads for random nodes
Also prints the number of edges that participate in at least one triad
"""
GraphClustCoeff = snap.GetClustCf(G)
print("Average clustering coefficient:", round(GraphClustCoeff, 4))
print("Number of triads:", snap.GetTriads(G))
NId = G.GetRndNId()
print(f'Clustering coefficient of random node {NId}:', round(snap.GetNodeClustCf(G, NId)))
NId = G.GetRndNId()
print(f'Number of triads random node {NId} participates:', snap.GetNodeTriads(G, NId))
print('Number of edges that participate in at least one triad:', snap.GetTriadEdges(G))
#b
EdgeBridgeV = snap.TIntPrV()
snap.GetEdgeBridges(fbsgel, EdgeBridgeV)
print("Number of edge bridges:", len(EdgeBridgeV))
#c
ArtNIdV = snap.TIntV()
snap.GetArtPoints(fbsgel, ArtNIdV)
print("Number of articulation points:", len(ArtNIdV))
#d Plot
snap.PlotSccDistr(fbsgel, "connected_comp_" + str(subgraph_name),
"connected_comp_" + str(subgraph_name))
#Q5
#a
print("Average clustering coefficient:", round(snap.GetClustCf(fbsgel, -1), 4))
#b
print("Number of triads:", snap.GetTriads(fbsgel, -1))
#c
RnId = fbsgel.GetRndNId(Rnd)
print("Clustering coefficient of random node " + str(RnId) + ":",
round(snap.GetNodeClustCf(fbsgel, RnId), 4))
#d
print("Number of triads random node " + str(RnId) + " participates:",
snap.GetNodeTriads(fbsgel, RnId))
#e
print("Number of edges that participate in at least one triad:",
snap.GetTriadEdges(fbsgel, -1))
#f Plot
snap.PlotClustCf(fbsgel, "clustering_coeff_" + str(subgraph_name),
"clustering_coeff_" + str(subgraph_name))
Art_points = snap.TIntV()
snap.GetArtPoints(Graph1, Art_points)
art = Art_points.Len()
print("Number of articulation points: ", art)
str2 = "connected_comp_" + file_name
snap.PlotSccDistr(Graph1, str2,
"Distribution of sizes of connected components")
#5.Connectivity and clustering in the network
avg_cc = snap.GetClustCf(Graph1, -1)
print("Average clustering coefficient: %0.4f" % avg_cc)
triads = snap.GetTriads(Graph1, -1)
print("Number of triads: ", triads)
random1 = Graph1.GetRndNId(Rnd)
node_cc = snap.GetNodeClustCf(Graph1, random1)
print("Clustering coefficient of random node %d: %0.4f" % (random1, node_cc))
random2 = Graph1.GetRndNId(Rnd)
node_triads = snap.GetNodeTriads(Graph1, random2)
print("Number of triads random node %d participates: %d" %
(random2, node_triads))
triad_edges = snap.GetTriadEdges(Graph1, -1)
print("Number of edges that participate in at least one triad: ", triad_edges)
str3 = "clustering_coeff_" + file_name
snap.PlotClustCf(Graph1, str3, "The distribution of clustering coefficient")
snap.PlotShortPathDistr(graph, "temp", "Undirected graph - shortest path")
os.system("mv diam.temp.png plots/shortest_path_" + subgraph_name + ".png")
os.system("rm diam.*")
print("Fraction of nodes in largest connected component:",
round(snap.GetMxSccSz(graph), 4))
print("Number of edge bridges:", get_bridges(graph).Len())
print("Number of articulation points:",
get_articulation_points(graph).Len())
snap.PlotSccDistr(graph, "temp", "Undirected graph - scc distribution")
os.system("mv scc.temp.png plots/connected_comp_" + subgraph_name + ".png")
os.system("rm scc.*")
print("Average clustering coefficient:", round(snap.GetClustCf(graph), 4))
print("Number of triads:", snap.GetTriads(graph))
random_node = graph.GetRndNId()
print("Clustering coefficient of random node", random_node, ":",
round(get_each_nodes_ClusteringCofficient(graph)[random_node], 4))
random_node = graph.GetRndNId()
print("Number of triads random node", random_node, "participates:",
snap.GetNodeTriads(graph, random_node))
print("Number of edges that participate in at least one triad:",
snap.GetTriadEdges(graph))
snap.PlotClustCf(graph, "temp",
"Undirected graph - clustering coefficient")
os.system("mv ccf.temp.png plots/clustering_coeff_" + subgraph_name +
".png")
os.system("rm ccf.*")
def graphStructure(elistName, elistPath):
"""
Calculate properties of the graph as given in the assignment
Args:
elistName (str) -> Input elist name
elistPath (pathlib.Path) -> Input elist using which graph needs to be built
Return:
RESULTS (dict) -> Dictionary containing results for different subparts of the assignment
"""
RESULTS = {}
subGraph = snap.LoadEdgeList(snap.PUNGraph, elistPath, 0, 1)
# Part 1 (Size of the network)
RESULTS['nodeCount'] = subGraph.GetNodes()
RESULTS['edgeCount'] = subGraph.GetEdges()
# Part 2 (Degree of nodes in the network)
maxDegree = 0
maxDegreeNodes = []
degree7Count = 0
for node in subGraph.Nodes():
if node.GetDeg() == 7:
degree7Count += 1
maxDegree = max(maxDegree, node.GetDeg())
for node in subGraph.Nodes():
if node.GetDeg() == maxDegree:
maxDegreeNodes.append(node.GetId())
plotFilename = f"deg_dist_{elistName}"
# Since it is an undirected graph, in/out degree is unimportant
snap.PlotOutDegDistr(subGraph, plotFilename)
RESULTS['maxDegree'] = maxDegree
RESULTS['maxDegreeNodes'] = ','.join(map(str, maxDegreeNodes))
RESULTS['degree7Count'] = degree7Count
# Part 3 (Paths in the network)
# Full Diameter Calculation
fullDiameters = {
10: snap.GetBfsFullDiam(subGraph, 10, False),
100: snap.GetBfsFullDiam(subGraph, 100, False),
1000: snap.GetBfsFullDiam(subGraph, 1000, False)
}
fullMean, fullVariance = meanVariance(fullDiameters.values())
fullDiameters['mean'] = fullMean
fullDiameters['variance'] = fullVariance
RESULTS['fullDiameters'] = fullDiameters
# Effective Diameter Calculation
effDiameters = {
10: snap.GetBfsEffDiam(subGraph, 10, False),
100: snap.GetBfsEffDiam(subGraph, 100, False),
1000: snap.GetBfsEffDiam(subGraph, 1000, False),
}
effMean, effVariance = meanVariance(effDiameters.values())
effDiameters['mean'] = effMean
effDiameters['variance'] = effVariance
RESULTS['effDiameters'] = effDiameters
plotFilename = f"shortest_path_{elistName}"
snap.PlotShortPathDistr(subGraph, plotFilename)
# Part 4 (Components of the network)
edgeBridges = snap.TIntPrV()
articulationPoints = snap.TIntV()
RESULTS['fractionLargestConnected'] = snap.GetMxSccSz(subGraph)
snap.GetEdgeBridges(subGraph, edgeBridges)
snap.GetArtPoints(subGraph, articulationPoints)
RESULTS['edgeBridges'] = len(edgeBridges)
RESULTS['articulationPoints'] = len(articulationPoints)
plotFilename = f"connected_comp_{elistName}"
snap.PlotSccDistr(subGraph, plotFilename)
# Part 5 (Connectivity and clustering in the network)
RESULTS['avgClusterCoefficient'] = snap.GetClustCf(subGraph, -1)
RESULTS['triadCount'] = snap.GetTriadsAll(subGraph, -1)[0]
nodeX = subGraph.GetRndNId(Rnd)
nodeY = subGraph.GetRndNId(Rnd)
RESULTS['randomClusterCoefficient'] = (nodeX,
snap.GetNodeClustCf(
subGraph, nodeX))
RESULTS['randomNodeTriads'] = (nodeY, snap.GetNodeTriads(subGraph, nodeY))
RESULTS['edgesTriads'] = snap.GetTriadEdges(subGraph)
plotFilename = f"clustering_coeff_{elistName}"
snap.PlotClustCf(subGraph, plotFilename)
return RESULTS
def main():
parentDir = os.getcwd()
os.chdir(parentDir + "/subgraphs")
sub_graph = snap.LoadEdgeList(snap.PUNGraph, sys.argv[1], 0, 1)
subGraphName = sys.argv[1].split(".")[0]
os.chdir(parentDir)
#### 1 ########
node_count = 0
for node in sub_graph.Nodes():
node_count = node_count + 1
printWithOutNewLine("Number of nodes:", node_count)
printWithOutNewLine("Number of edges:", snap.CntUniqBiDirEdges(sub_graph))
#### 2 ########
printWithOutNewLine("Number of nodes with degree=7:",
snap.CntDegNodes(sub_graph, 7))
rndMaxDegNId = snap.GetMxDegNId(sub_graph)
nodeDegPairs = snap.TIntPrV()
snap.GetNodeInDegV(sub_graph, nodeDegPairs)
maxDegVal = 0
for pair in nodeDegPairs:
if (pair.GetVal1() == rndMaxDegNId):
maxDegVal = pair.GetVal2()
break
maxDegNodes = []
for pair in nodeDegPairs:
if (pair.GetVal2() == maxDegVal):
maxDegNodes.append(pair.GetVal1())
print("Node id(s) with highest degree:", end=" ")
print(*maxDegNodes, sep=',')
#### 3 ########
sampledFullDiam = []
sampledFullDiam.append(snap.GetBfsFullDiam(sub_graph, 10, False))
sampledFullDiam.append(snap.GetBfsFullDiam(sub_graph, 100, False))
sampledFullDiam.append(snap.GetBfsFullDiam(sub_graph, 1000, False))
sampledFullDiamStats = []
sampledFullDiamStats.append(round(statistics.mean(sampledFullDiam), 4))
sampledFullDiamStats.append(round(statistics.variance(sampledFullDiam), 4))
printWithOutNewLine("Approximate full diameter by sampling 10 nodes:",
sampledFullDiam[0])
printWithOutNewLine("Approximate full diameter by sampling 100 nodes:",
sampledFullDiam[1])
printWithOutNewLine("Approximate full diameter by sampling 1000 nodes:",
sampledFullDiam[2])
print("Approximate full diameter (mean and variance):", end=" ")
print(*sampledFullDiamStats, sep=',')
sampledEffDiam = []
sampledEffDiam.append(round(snap.GetBfsEffDiam(sub_graph, 10, False), 4))
sampledEffDiam.append(round(snap.GetBfsEffDiam(sub_graph, 100, False), 4))
sampledEffDiam.append(round(snap.GetBfsEffDiam(sub_graph, 1000, False), 4))
sampledEffDiamStats = []
sampledEffDiamStats.append(round(statistics.mean(sampledEffDiam), 4))
sampledEffDiamStats.append(round(statistics.variance(sampledEffDiam), 4))
printWithOutNewLine("Approximate effective diameter by sampling 10 nodes:",
sampledEffDiam[0])
printWithOutNewLine(
"Approximate effective diameter by sampling 100 nodes:",
sampledEffDiam[1])
printWithOutNewLine(
"Approximate effective diameter by sampling 1000 nodes:",
sampledEffDiam[2])
print("Approximate effective diameter (mean and variance):", end=" ")
print(*sampledEffDiamStats, sep=',')
#### 4 ########
printWithOutNewLine("Fraction of nodes in largest connected component:",
round(snap.GetMxSccSz(sub_graph), 4))
bridgeEdges = snap.TIntPrV()
snap.GetEdgeBridges(sub_graph, bridgeEdges)
printWithOutNewLine("Number of edge bridges:", len(bridgeEdges))
articulationPoints = snap.TIntV()
snap.GetArtPoints(sub_graph, articulationPoints)
printWithOutNewLine("Number of articulation points:",
len(articulationPoints))
#### 5 ########
printWithOutNewLine("Average clustering coefficient:",
round(snap.GetClustCf(sub_graph, -1), 4))
printWithOutNewLine("Number of triads:", snap.GetTriads(sub_graph, -1))
randomNodeId = sub_graph.GetRndNId()
nodeIdCcfMap = snap.TIntFltH()
snap.GetNodeClustCf(sub_graph, nodeIdCcfMap)
print("Clustering coefficient of random node", end=" ")
print(randomNodeId, end=": ")
print(round(nodeIdCcfMap[randomNodeId], 4))
print("Number of triads random node", end=" ")
print(randomNodeId, end=" participates: ")
print(snap.GetNodeTriads(sub_graph, randomNodeId))
printWithOutNewLine(
"Number of edges that participate in at least one triad:",
snap.GetTriadEdges(sub_graph, -1))
#### plots ########
if not os.path.isdir('plots'):
os.makedirs('plots')
os.chdir(parentDir + "/plots")
plotsDir = os.getcwd()
snap.PlotOutDegDistr(sub_graph, subGraphName,
subGraphName + " Subgraph Degree Distribution")
snap.PlotShortPathDistr(
sub_graph, subGraphName,
subGraphName + " Subgraph Shortest Path Lengths Distribution")
snap.PlotSccDistr(
sub_graph, subGraphName,
subGraphName + " Subgraph Connected Components Size Distribution")
snap.PlotClustCf(
sub_graph, subGraphName,
subGraphName + " Subgraph Clustering Coefficient Distribution")
files = os.listdir(plotsDir)
for file in files:
if not file.endswith(".png"):
os.remove(os.path.join(plotsDir, file))
plots = os.listdir(plotsDir)
filePrefix = "filename"
for file in plots:
nameSplit = file.split(".")
if (len(nameSplit) == 2):
continue
if (nameSplit[0] == "ccf"):
filePrefix = "clustering_coeff_"
elif (nameSplit[0] == "outDeg"):
filePrefix = "deg_dist_"
elif (nameSplit[0] == "diam"):
filePrefix = "shortest_path_"
elif (nameSplit[0] == "scc"):
filePrefix = "connected_comp_"
os.rename(file, filePrefix + nameSplit[1] + "." + nameSplit[2])
os.chdir(parentDir)
# Number of node Triads of a random node
print "Number of triads of random node " + str(
RandNode3) + " participates in email-Enron-subgraph: " + str(
snap.GetNodeTriads(email_enron_subgraph, RandNode3))
if (sub_graph_name == "p2p-Gnutella04-subgraph"):
# Number of node Triads of a random node
print "Number of triads of random node " + str(
RandNode4) + " participates in p2p-Gnutella04-subgraph: " + str(
snap.GetNodeTriads(p2p_gnutella04_subgraph, RandNode4))
# Task 1.2.5.5
if (sub_graph_name == "soc-Epinions1-subgraph"):
# Calculating no of edges in particular triads
print "Number of edges that participate in at least one triad in soc-Epinions1-subgraph : " + str(
snap.GetTriadEdges(soc_epinions1_subgraph))
if (sub_graph_name == "cit-HepPh-subgraph"):
# Calculating no of edges in particular triads
print "Number of edges that participate in at least one triad in cit-HepPh-subgraph : " + str(
snap.GetTriadEdges(cit_heph_subgraph))
if (sub_graph_name == "email-Enron-subgraph"):
# Calculating no of edges in particular triads
print "Number of edges that participate in at least one triad in email-Enron-subgraph : " + str(
snap.GetTriadEdges(email_enron_subgraph))
if (sub_graph_name == "p2p-Gnutella04-subgraph"):
# Calculating no of edges in particular triads
print "Number of edges that participate in at least one triad in p2p-Gnutella04-subgraph : " + str(
snap.GetTriadEdges(p2p_gnutella04_subgraph))
# Task 1.2.5.6
if (sub_graph_name == "soc-Epinions1-subgraph"):
print("Average clustering coefficient: {}".format(round(cluster_coeff, 4)))
num_triads = snap.GetTriads(G, -1)
print("Number of triads: {}".format(num_triads))
node_id = G.GetRndNId(Rnd)
node_cluster_coeff = snap.GetNodeClustCf(G, node_id)
print("Clustering coefficient of random node {}: {}".format(
node_id, round(node_cluster_coeff, 4)))
node_id = G.GetRndNId(Rnd)
node_num_triads = snap.GetNodeTriads(G, node_id)
print("Number of triads random node {} participates: {}".format(
node_id, node_num_triads))
triad_edge = snap.GetTriadEdges(G)
print("Number of edges that participate in at least one triad: {}".format(
triad_edge))
cf_dist = snap.TFltPrV()
coeff = snap.GetClustCf(G, cf_dist, -1)
degree_coeff = {}
for pair in cf_dist:
degree_coeff[pair.GetVal1()] = pair.GetVal2()
# Plot Degree Distribution
plot_filename = 'clustering_coeff_' + graph_filename[:-6] + '.png'
plot_filedir = os.path.join(plotpath, plot_filename)
plt.figure()
plt.scatter(list(degree_coeff.keys()), list(degree_coeff.values()), s=10)
plt.xlabel("Degree")
d[Community].append(NI)
NodeIdList.Add(NI)
SubGraph = snap.GetSubGraph(G1, NodeIdList)
diam = snap.GetBfsFullDiam(SubGraph, 100, False)
print "The diametre is %d" % diam
DegToCCfV = snap.TFltPrV()
DegList = list()
result = snap.GetClustCfAll(SubGraph, DegToCCfV)
for item in DegToCCfV:
DegList.append(item.GetVal1())
#print "degree: %d, clustering coefficient: %f" % (item.GetVal1(), item.GetVal2())
print "average clustering coefficient", result[0]
print "closed triads", result[1]
print "open triads", result[2]
NumTriadEdges = snap.GetTriadEdges(SubGraph)
print "The number of TriadEdges is %d" % NumTriadEdges
CountEdges = snap.CntUniqUndirEdges(SubGraph)
print "Directed Graph: Count of undirected edges is %d" % CountEdges
CountNodes = SubGraph.GetNodes()
InternalDensity = CountEdges / (CountNodes * (CountNodes - 1) * 0.5)
print "The Internal Density is %f" % InternalDensity
AvgDeg = 2 * CountEdges / CountNodes
print "The Average Degree is %f" % AvgDeg
MedianDegree = np.median(DegList)
print "The Median Degree is %d" % MedianDegree
TPR = NumTriadEdges / CountEdges
print "The Triangle Participation Rate is %d" % TPR
NodeIdList.Clr()
print "The modularity of the network is %f" % modularity
EdgeV = snap.TIntPrV()
snap.GetEdgeBridges(G, EdgeV)
print("Number of edge bridges:", len(EdgeV))
ArtNIdV = snap.TIntV()
snap.GetArtPoints(G, ArtNIdV)
print("Number of articulation points:", len(ArtNIdV))
print("Average clustering coefficient: %.4f" % snap.GetClustCf(G, -1))
print("Number of triads:", snap.GetTriads(G, -1))
Ran_n = G.GetRndNId(Rnd)
print("Clustering coefficient of random node %d: %.4f" %
(Ran_n, snap.GetNodeClustCf(G, Ran_n)))
Ran_n = G.GetRndNId(Rnd)
print("Number of triads random node %d participates: %d" %
(Ran_n, snap.GetNodeTriads(G, Ran_n)))
print("Number of edges that participate in at least one triad:",
snap.GetTriadEdges(G))
snap.PlotInDegDistr(G, "D_" + sys.argv[1], "Degree Distribution")
MoveFile(os.path.join(dirname, "inDeg.D_" + sys.argv[1] + ".png"),
os.path.join(dirname, "plots", "deg_dist_" + sys.argv[1] + ".png"))
snap.PlotShortPathDistr(G, "S_" + sys.argv[1], "Shortest path Distribution")
MoveFile(
os.path.join(dirname, "diam.S_" + sys.argv[1] + ".png"),
os.path.join(dirname, "plots", "shortest_path_" + sys.argv[1] + ".png"))
snap.PlotSccDistr(G, "C_" + sys.argv[1], "Component Size Distribution")
MoveFile(
os.path.join(dirname, "scc.C_" + sys.argv[1] + ".png"),
os.path.join(dirname, "plots", "connected_comp_" + sys.argv[1] + ".png"))
## Connected Components Distribution
sn.PlotSccDistr(graph, name, "Connected Component Distribution")
plotRemove("scc", "connected_comp", name)
#Question 5
## Clustering Coefficient
print("Average clustering coefficient: {:0.4f}".format(
sn.GetClustCf(graph)))
## Triads
print("Number of triads: {}".format(sn.GetTriads(graph)))
## Random Clustering Coefficient
rndNode = graph.GetRndNId()
print("Clustering coefficient of random node {}: {:0.4f}".format(
rndNode, sn.GetNodeClustCf(graph, rndNode)))
## Random node triads
rndNode = graph.GetRndNId()
print("Number of triads random node {} participates: {}".format(
rndNode, sn.GetNodeTriads(graph, rndNode)))
## Edges in Triads
print("Number of edges that participate in at least one triad: {}".format(
sn.GetTriadEdges(graph)))
## Plot Clustering Coefficient
sn.PlotClustCf(graph, name, "Clustering Coefficient Distribution")
plotRemove("ccf", "clustering_coeff", name)
def ratioTriadEdges(G):
return snap.GetTriadEdges(G) / float(G.GetEdges())
