Exemple #1
0
// Test the default constructor
TEST(TNGraph, DefaultConstructor) {
  PNGraph Graph;

  Graph = TNGraph::New();

  EXPECT_EQ(0,Graph->GetNodes());
  EXPECT_EQ(0,Graph->GetEdges());

  EXPECT_EQ(1,Graph->IsOk());
  EXPECT_EQ(1,Graph->Empty());
  EXPECT_EQ(1,Graph->HasFlag(gfDirected));
}
Exemple #2
0
// Test small graph
TEST(TNGraph, GetSmallGraph) {
  PNGraph Graph;

  Graph = TNGraph::GetSmallGraph();

  EXPECT_EQ(5,Graph->GetNodes());
  EXPECT_EQ(6,Graph->GetEdges());

  EXPECT_EQ(1,Graph->IsOk());
  EXPECT_EQ(0,Graph->Empty());
  EXPECT_EQ(1,Graph->HasFlag(gfDirected));
}
Exemple #3
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// Print graph statistics
void PrintGStats(const char s[], PNGraph Graph) {
  printf("graph %s, nodes %d, edges %d, empty %s\n",
      s, Graph->GetNodes(), Graph->GetEdges(),
      Graph->Empty() ? "yes" : "no");
}
Exemple #4
0
// Test node, edge creation
void ManipulateNodesEdges() {
  int NNodes = 10000;
  int NEdges = 100000;
  const char *FName = "demo.graph.dat";

  PNGraph Graph;
  PNGraph Graph1;
  PNGraph Graph2;
  int i;
  int n;
  int NCount;
  int ECount1;
  int ECount2;
  int x,y;
  bool t;

  Graph = TNGraph::New();
  t = Graph->Empty();

  // create the nodes
  for (i = 0; i < NNodes; i++) {
    Graph->AddNode(i);
  }
  t = Graph->Empty();
  n = Graph->GetNodes();

  // create random edges
  NCount = NEdges;
  while (NCount > 0) {
    x = rand() % NNodes;
    y = rand() % NNodes;
    // Graph->GetEdges() is not correct for the loops (x == y),
    // skip the loops in this test
    if (x != y  &&  !Graph->IsEdge(x,y)) {
      n = Graph->AddEdge(x, y);
      NCount--;
    }
  }
  PrintGStats("ManipulateNodesEdges:Graph",Graph);

  // get all the nodes
  NCount = 0;
  for (TNGraph::TNodeI NI = Graph->BegNI(); NI < Graph->EndNI(); NI++) {
    NCount++;
  }

  // get all the edges for all the nodes
  ECount1 = 0;
  for (TNGraph::TNodeI NI = Graph->BegNI(); NI < Graph->EndNI(); NI++) {
    for (int e = 0; e < NI.GetOutDeg(); e++) {
      ECount1++;
    }
  }

  // get all the edges directly
  ECount2 = 0;
  for (TNGraph::TEdgeI EI = Graph->BegEI(); EI < Graph->EndEI(); EI++) {
    ECount2++;
  }
  printf("ManipulateNodesEdges:Graph, nodes %d, edges1 %d, edges2 %d\n",
      NCount, ECount1, ECount2);

  // assignment
  Graph1 = TNGraph::New();
  *Graph1 = *Graph;
  PrintGStats("ManipulateNodesEdges:Graph1",Graph1);

  // save the graph
  {
    TFOut FOut(FName);
    Graph->Save(FOut);
    FOut.Flush();
  }

  // load the graph
  {
    TFIn FIn(FName);
    Graph2 = TNGraph::Load(FIn);
  }
  PrintGStats("ManipulateNodesEdges:Graph2",Graph2);

  // remove all the nodes and edges
  for (i = 0; i < NNodes; i++) {
    n = Graph->GetRndNId();
    Graph->DelNode(n);
  }

  PrintGStats("ManipulateNodesEdges:Graph",Graph);

  Graph1->Clr();
  PrintGStats("ManipulateNodesEdges:Graph1",Graph1);
}
	int main(int argc, char* argv[]) {

		string edge="";
		const char *edge1 ="";
		char * s1;
		char * s2;
		int from,to,a[2],j=0,RndFullDiam,SmallWorlFullDiam,PrefAttachFullDiam,i,t, FullDiam;
		int64 triad; 
		double RndclusteringCoeff,PrefAttachclusteringCoeff,SmallWorldclusteringCoeff,clusteringCoeff;
		double numStrongComp,RndEffDiam, RndAvgPL, SmallWorldEffDiam, SmallWorldAvgPL, PrefAttachEffDiam, PrefAttachAvgPL,EffDiam,AvgPL;  
		PNGraph Graph;
		PUNGraph RandomGraph, PrefAttach, SmallWorld;
		TIntPrV edges;
		TIntFltH PRank;
		TIntPrV Bridges;
		TFltV EigV;

		ofstream P1_measures,P2_measures,P3_measures,bridges;
		P1_measures.open("P1_measures.txt");
		P2_measures.open("P2_measures.txt");
		P3_measures.open("P3_measures.txt");
		bridges.open("Bridges.txt");
		
		cout<<"\n loading SNAP Graph";
		//Graph = TSnap::LoadEdgeList<PNGraph>("SnapGraph.txt",0,1);
		Graph = TNGraph::New();
		t = Graph->Empty();
		for (i = 1; i < 78697; i++) {
			cout<<"adding Node"<<i<<"\n";
		Graph->AddNode(i);
		}

		//Reading the Annonymized List and creating the SNAP graph
		ifstream gwfile;
		gwfile.open("annonymized_edge_List.csv");
		if(!gwfile) {
		cout << "FAILED: file could not be opened" << endl << "Press enter to close.";
		cin.get();
		return 0;
		}else
		cout << "SUCCESSFULLY opened file!\n";
		cout << "-------------------------\n\n\n";
	
		while(getline(gwfile, edge,'\n')){
			edge1=edge.c_str();
			s1 = strtok ((char *)edge1,",");
			s2 = strtok (NULL,",");
			from = atoi(s1);
			to = atoi(s2);
			Graph->AddEdge(from,to);
			cout<<"Adding Edge"<<from<<"->"<<to<<endl;
		}
		TSnap::SaveEdgeList(Graph, "SnapGraph.txt", "File saved as Tab separated");
		cout<<"\n graph loaded";
		PUNGraph UG = TSnap::ConvertGraph<PUNGraph>(Graph);
		
		//									P1 Measure
		// Bridges
		GetEdgeBridges(UG, Bridges);
		bridges << "\nNumber of Bridges : " << Bridges.Len() <<endl;
		for(int i = 0; i<Bridges.Len(); i++)
		{
			bridges << Bridges[i].Val1 << "->" << Bridges[i].Val2 <<endl; 
		}

		// Triads
		triad = TSnap::GetTriads(Graph);
		P1_measures << "\nNumber of triads : " << triad <<endl;

		
		
		//									P2 Measure
		// Global Clustering Coefficient
		clusteringCoeff= TSnap::GetClustCf(Graph);
		P2_measures << "\nGlobal Clustering Coefficient : " << clusteringCoeff<<"\n\n";
		
		// Top 3 PageRank Values
		GetPageRank(Graph,PRank);
		P2_measures << "\nTop 3 Page Rank : " << "\n1st : "<< PRank[0].Val << "\n2nd : "<< PRank[1].Val << "\n3rd : "<< PRank[2].Val <<endl;

		// Top 3 Eigenvector centrality Values
		TSnap::GetEigVec(UG, EigV);
		P2_measures << "\nTop 3 EigenVector Centralities: "<< "\n1st : "<< EigV[0].Val << "\n2nd : "<< EigV[1].Val << "\n3rd : "<< EigV[2].Val <<endl;

			
		//							P3 Models and Measures With 5000 Nodes and Average Degree 4 as that of Twitter Graph
		// Creating Random graph
		RandomGraph = TSnap::GenRndDegK(5000,4);
		PrintGStats("Random Graph" , TSnap::ConvertGraph<PNGraph>(RandomGraph));
		cout<<"\n Random graph created \n";
		TSnap::SaveEdgeList(RandomGraph, "RandomGraph.tsv", "File saved as Tab separated");
		TSnap::GetBfsEffDiam(RandomGraph, 5000, true, RndEffDiam, RndFullDiam, RndAvgPL);
		RndclusteringCoeff= TSnap::GetClustCf(RandomGraph);
		
		P3_measures << "\n\n\nRandom Graph with 5000 nodes and Average Degree 4: ";
		P3_measures << "\nAverage Path Length : "<< RndAvgPL;
		P3_measures << "\nClustering Coefficient : "<< RndclusteringCoeff;

		// Creating Small World Model Graph
		SmallWorld = TSnap::GenSmallWorld(5000,4,0.05);
		PrintGStats("Small World Graph" , TSnap::ConvertGraph<PNGraph>(SmallWorld));
		TSnap::SaveEdgeList(SmallWorld, "SmallWorld.tsv", "File saved as Tab separated");
		cout<<"\n SmallWorld graph created \n";
		TSnap::GetBfsEffDiam(SmallWorld, 5000, true, SmallWorldEffDiam, SmallWorlFullDiam, SmallWorldAvgPL);
		SmallWorldclusteringCoeff= TSnap::GetClustCf(SmallWorld);
		
		P3_measures << "\n\n\nSmall World Graph with 5000 nodes and Average Degree 4 and Beta .05: ";
		P3_measures << "\nAverage Path Length : "<< SmallWorldAvgPL;
		P3_measures << "\nClustering Coefficient : "<< SmallWorldclusteringCoeff;
		

		// Creating Prefrential Attachment Model Graph
		PrefAttach = TSnap::GenPrefAttach(5000,4);
		PrintGStats("Prefrential Graph" , TSnap::ConvertGraph<PNGraph>(PrefAttach));
		TSnap::SaveEdgeList(PrefAttach, "PrefrentialGraph.tsv", "File saved as Tab separated");
		cout<<"\n PrefAttach graph created \n";
		TSnap::GetBfsEffDiam(PrefAttach, 5000, true, PrefAttachEffDiam, PrefAttachFullDiam, PrefAttachAvgPL);
		PrefAttachclusteringCoeff= TSnap::GetClustCf(PrefAttach);
		cout<<"\n PrefAttach graph created";
		P3_measures << "\n\n\nPrefrential Graph with 5000 nodes and Average Degree 4 : ";
		P3_measures << "\nAverage Path Length : "<< PrefAttachAvgPL;
		P3_measures << "\nClustering Coefficient : "<< PrefAttachclusteringCoeff;*/

		// Diameter and Average Path Length
		TSnap::GetBfsEffDiam(Graph, 78696, true, EffDiam, FullDiam,AvgPL);
		P1_measures << "\nDiameter : " << FullDiam<<endl;
		P1_measures << "\nAverage Path Length : " << AvgPL<<endl;

		P1_measures.close();
		P2_measures.close();
		P3_measures.close();
		bridges.close();

	return 0;
	}
Exemple #6
0
// Test node, edge creation
TEST(TNGraph, ManipulateNodesEdges) {
  int NNodes = 10000;
  int NEdges = 100000;
  const char *FName = "test.graph.dat";

  PNGraph Graph;
  PNGraph Graph1;
  PNGraph Graph2;
  int i;
  int n;
  int NCount;
  int x,y;
  int Deg, InDeg, OutDeg;

  Graph = TNGraph::New();
  EXPECT_EQ(1,Graph->Empty());

  // create the nodes
  for (i = 0; i < NNodes; i++) {
    Graph->AddNode(i);
  }
  EXPECT_EQ(0,Graph->Empty());
  EXPECT_EQ(NNodes,Graph->GetNodes());

  // create random edges
  NCount = NEdges;
  while (NCount > 0) {
    x = (long) (drand48() * NNodes);
    y = (long) (drand48() * NNodes);
    // Graph->GetEdges() is not correct for the loops (x == y),
    // skip the loops in this test
    if (x != y  &&  !Graph->IsEdge(x,y)) {
      n = Graph->AddEdge(x, y);
      NCount--;
    }
  }

  EXPECT_EQ(NEdges,Graph->GetEdges());

  EXPECT_EQ(0,Graph->Empty());
  EXPECT_EQ(1,Graph->IsOk());

  for (i = 0; i < NNodes; i++) {
    EXPECT_EQ(1,Graph->IsNode(i));
  }

  EXPECT_EQ(0,Graph->IsNode(NNodes));
  EXPECT_EQ(0,Graph->IsNode(NNodes+1));
  EXPECT_EQ(0,Graph->IsNode(2*NNodes));

  // nodes iterator
  NCount = 0;
  for (TNGraph::TNodeI NI = Graph->BegNI(); NI < Graph->EndNI(); NI++) {
    NCount++;
  }
  EXPECT_EQ(NNodes,NCount);

  // edges per node iterator
  NCount = 0;
  for (TNGraph::TNodeI NI = Graph->BegNI(); NI < Graph->EndNI(); NI++) {
    for (int e = 0; e < NI.GetOutDeg(); e++) {
      NCount++;
    }
  }
  EXPECT_EQ(NEdges,NCount);

  // edges iterator
  NCount = 0;
  for (TNGraph::TEdgeI EI = Graph->BegEI(); EI < Graph->EndEI(); EI++) {
    NCount++;
  }
  EXPECT_EQ(NEdges,NCount);

  // node degree
  for (TNGraph::TNodeI NI = Graph->BegNI(); NI < Graph->EndNI(); NI++) {
    Deg = NI.GetDeg();
    InDeg = NI.GetInDeg();
    OutDeg = NI.GetOutDeg();

    EXPECT_EQ(Deg,InDeg+OutDeg);
  }

  // assignment
  Graph1 = TNGraph::New();
  *Graph1 = *Graph;

  EXPECT_EQ(NNodes,Graph1->GetNodes());
  EXPECT_EQ(NEdges,Graph1->GetEdges());
  EXPECT_EQ(0,Graph1->Empty());
  EXPECT_EQ(1,Graph1->IsOk());

  // saving and loading
  {
    TFOut FOut(FName);
    Graph->Save(FOut);
    FOut.Flush();
  }

  {
    TFIn FIn(FName);
    Graph2 = TNGraph::Load(FIn);
  }

  EXPECT_EQ(NNodes,Graph2->GetNodes());
  EXPECT_EQ(NEdges,Graph2->GetEdges());
  EXPECT_EQ(0,Graph2->Empty());
  EXPECT_EQ(1,Graph2->IsOk());

  // remove all the nodes and edges
  for (i = 0; i < NNodes; i++) {
    n = Graph->GetRndNId();
    Graph->DelNode(n);
  }

  EXPECT_EQ(0,Graph->GetNodes());
  EXPECT_EQ(0,Graph->GetEdges());

  EXPECT_EQ(1,Graph->IsOk());
  EXPECT_EQ(1,Graph->Empty());

  Graph1->Clr();

  EXPECT_EQ(0,Graph1->GetNodes());
  EXPECT_EQ(0,Graph1->GetEdges());

  EXPECT_EQ(1,Graph1->IsOk());
  EXPECT_EQ(1,Graph1->Empty());
}