d0/d63/agm_8cpp_source.html

 #include "stdafx.h"

 #include "Snap.h"

 #include "agm.h"

 #include "agmfit.h"


 // AGM graph generation.


 void TAGM::RndConnectInsideCommunity(PUNGraph& Graph, const TIntV& CmtyV, const double& Prob, TRnd& Rnd){

   int CNodes = CmtyV.Len(), CEdges;

   if (CNodes < 20) {

     CEdges = (int) Rnd.GetBinomialDev(Prob, CNodes * (CNodes-1) / 2);

   } else {

     CEdges = (int) (Prob * CNodes * (CNodes - 1) / 2);

   }

   THashSet<TIntPr> NewEdgeSet(CEdges);

   for (int edge = 0; edge < CEdges; ) {

     int SrcNId = CmtyV[Rnd.GetUniDevInt(CNodes)];

     int DstNId = CmtyV[Rnd.GetUniDevInt(CNodes)];

     if (SrcNId > DstNId) { Swap(SrcNId,DstNId); }

     if (SrcNId != DstNId && ! NewEdgeSet.IsKey(TIntPr(SrcNId, DstNId))) { // is new edge

       NewEdgeSet.AddKey(TIntPr(SrcNId, DstNId));

       Graph->AddEdge(SrcNId, DstNId);

       edge++;

     }

   }

 }


 PUNGraph TAGM::GenAGM(TVec<TIntV>& CmtyVV, const double& DensityCoef, const int TargetEdges, TRnd& Rnd){

   PUNGraph TryG = TAGM::GenAGM(CmtyVV, DensityCoef, 1.0, Rnd);

   const double ScaleCoef = (double) TargetEdges / (double) TryG->GetEdges();

   return TAGM::GenAGM(CmtyVV, DensityCoef, ScaleCoef, Rnd);

 }


 PUNGraph TAGM::GenAGM(TVec<TIntV>& CmtyVV, const double& DensityCoef, const double& ScaleCoef, TRnd& Rnd){

   TFltV CProbV;

   double Prob;

   for (int i = 0; i < CmtyVV.Len(); i++) {

     Prob = ScaleCoef*pow( double( CmtyVV[i].Len()), - DensityCoef);

     if (Prob > 1.0) { Prob = 1; }

     CProbV.Add(Prob);

   }

   return TAGM::GenAGM(CmtyVV, CProbV, Rnd);

 }


 PUNGraph TAGM::GenAGM(TVec<TIntV>& CmtyVV, const TFltV& CProbV, TRnd& Rnd, const double PNoCom){

   PUNGraph G = TUNGraph::New(100 * CmtyVV.Len(), -1);

   printf("AGM begins\n");

   for (int i = 0; i < CmtyVV.Len(); i++) {

     TIntV& CmtyV = CmtyVV[i];

     for (int u = 0; u < CmtyV.Len(); u++) {

       if ( G->IsNode(CmtyV[u])) { continue; }

       G->AddNode(CmtyV[u]);

     }

     double Prob = CProbV[i];

     RndConnectInsideCommunity(G, CmtyV, Prob, Rnd);

   }

   if (PNoCom > 0.0) { //if we want to connect nodes that do not share any community

     TIntSet NIDS;

     for (int c = 0; c < CmtyVV.Len(); c++) {

       for (int u = 0; u < CmtyVV[c].Len(); u++) {

         NIDS.AddKey(CmtyVV[c][u]);

       }

     }

     TIntV NIDV;

     NIDS.GetKeyV(NIDV);

     RndConnectInsideCommunity(G,NIDV,PNoCom,Rnd);

   }

   printf("AGM completed (%d nodes %d edges)\n",G->GetNodes(),G->GetEdges());

   G->Defrag();

   return G;

 }


 void TAGMUtil::GenPLSeq(TIntV& SzSeq, const int& SeqLen, const double& Alpha, TRnd& Rnd, const int& Min, const int& Max) {

   SzSeq.Gen(SeqLen, 0);

   while (SzSeq.Len() < SeqLen) {

     int Sz = (int) TMath::Round(Rnd.GetPowerDev(Alpha));

     if (Sz >= Min && Sz <= Max) {

       SzSeq.Add(Sz);

     }

   }

 }


 void TAGMUtil::GenCmtyVVFromPL(TVec<TIntV>& CmtyVV, const int& Nodes, const int& Coms, const double& ComSzAlpha, const double& MemAlpha, const int& MinSz, const int& MaxSz, const int& MinK, const int& MaxK, TRnd& Rnd){

   TIntV NIDV(Nodes, 0);

   for (int i = 0; i < Nodes; i++) {

     NIDV.Add(i);

   }

   GenCmtyVVFromPL(CmtyVV, NIDV, Nodes, Coms, ComSzAlpha, MemAlpha, MinSz, MaxSz, MinK, MaxK, Rnd);

 }


 void TAGMUtil::GenCmtyVVFromPL(TVec<TIntV>& CmtyVV, const PUNGraph& Graph, const int& Nodes, const int& Coms, const double& ComSzAlpha, const double& MemAlpha, const int& MinSz, const int& MaxSz, const int& MinK, const int& MaxK, TRnd& Rnd){

   if (Coms == 0 || Nodes == 0) {

     CmtyVV.Clr();

     return;

   }

   TIntV NIDV;

   Graph->GetNIdV(NIDV);

   GenCmtyVVFromPL(CmtyVV, NIDV, Nodes, Coms, ComSzAlpha, MemAlpha, MinSz, MaxSz, MinK, MaxK, Rnd);

 }


 void TAGMUtil::GenCmtyVVFromPL(TVec<TIntV>& CmtyVV, const TIntV& NIDV, const int& Nodes, const int& Coms, const double& ComSzAlpha, const double& MemAlpha, const int& MinSz, const int& MaxSz, const int& MinK, const int& MaxK, TRnd& Rnd){

   if (Coms == 0 || Nodes == 0) {

     CmtyVV.Clr();

     return;

   }

   TIntV ComSzSeq, MemSeq;

   TAGMUtil::GenPLSeq(ComSzSeq,Coms,ComSzAlpha,Rnd,MinSz,MaxSz);

   TAGMUtil::GenPLSeq(MemSeq,Nodes,MemAlpha,Rnd,MinK,MaxK);

   TIntPrV CIDSzPrV, NIDMemPrV;

   for (int i = 0; i < ComSzSeq.Len(); i++) {

     CIDSzPrV.Add(TIntPr(i, ComSzSeq[i]));

   }

   for (int i = 0; i < MemSeq.Len(); i++) {

     NIDMemPrV.Add(TIntPr(NIDV[i], MemSeq[i]));

   }

   TAGMUtil::ConnectCmtyVV(CmtyVV, CIDSzPrV, NIDMemPrV, Rnd);

 }


 void TAGMUtil::ConnectCmtyVV(TVec<TIntV>& CmtyVV, const TIntPrV& CIDSzPrV, const TIntPrV& NIDMemPrV, TRnd& Rnd) {

   const int Nodes = NIDMemPrV.Len(), Coms = CIDSzPrV.Len();

   TIntV NDegV,CDegV;

   TIntPrSet CNIDSet;

   TIntSet HitNodes(Nodes);

   THash<TInt,TIntV> CmtyVH;

   for (int i = 0;i < CIDSzPrV.Len(); i++) {

     for (int j = 0; j < CIDSzPrV[i].Val2; j++) {

       CDegV.Add(CIDSzPrV[i].Val1);

     }

   }

   for (int i = 0; i < NIDMemPrV.Len(); i++) {

     for (int j = 0; j < NIDMemPrV[i].Val2; j++) {

       NDegV.Add(NIDMemPrV[i].Val1);

     }

   }

   while (CDegV.Len() < (int) (1.2 * Nodes)) {

     CDegV.Add(CIDSzPrV[Rnd.GetUniDevInt(Coms)].Val1);

   }

   while (NDegV.Len() < CDegV.Len()) {

     NDegV.Add(NIDMemPrV[Rnd.GetUniDevInt(Nodes)].Val1);

   }

   printf("Total Mem: %d, Total Sz: %d\n",NDegV.Len(), CDegV.Len());

   int c=0;

   while (c++ < 15 && CDegV.Len() > 1) {

     for (int i = 0; i < CDegV.Len(); i++) {

       int u = Rnd.GetUniDevInt(CDegV.Len());

       int v = Rnd.GetUniDevInt(NDegV.Len());

       if (CNIDSet.IsKey(TIntPr(CDegV[u], NDegV[v]))) { continue; }

       CNIDSet.AddKey(TIntPr(CDegV[u], NDegV[v]));

       HitNodes.AddKey(NDegV[v]);

       if (u == CDegV.Len() - 1) { CDegV.DelLast(); }

       else {

         CDegV[u] = CDegV.Last();

         CDegV.DelLast();

       }

       if (v == NDegV.Len() - 1) { NDegV.DelLast(); }

       else {

         NDegV[v] = NDegV.Last();

         NDegV.DelLast();

       }

     }

   }

   //make sure that every node belongs to at least one community

   for (int i = 0; i < Nodes; i++) {

     int NID = NIDMemPrV[i].Val1;

     if (! HitNodes.IsKey(NID)) {

       CNIDSet.AddKey(TIntPr(CIDSzPrV[Rnd.GetUniDevInt(Coms)].Val1, NID));

       HitNodes.AddKey(NID);

     }

   }

   IAssert(HitNodes.Len() == Nodes);

   for (int i = 0; i < CNIDSet.Len(); i++) {

     TIntPr CNIDPr = CNIDSet[i];

     CmtyVH.AddDat(CNIDPr.Val1);

     CmtyVH.GetDat(CNIDPr.Val1).Add(CNIDPr.Val2);

   }

   CmtyVH.GetDatV(CmtyVV);

 }


 void TAGMUtil::RewireCmtyVV(const TVec<TIntV>& CmtyVVIn, TVec<TIntV>& CmtyVVOut, TRnd& Rnd){

   THash<TInt,TIntV> CmtyVH;

   for (int i = 0; i < CmtyVVIn.Len(); i++) {

     CmtyVH.AddDat(i, CmtyVVIn[i]);

   }

   TAGMUtil::RewireCmtyNID(CmtyVH, Rnd);

   CmtyVH.GetDatV(CmtyVVOut);

 }


 void TAGMUtil::RewireCmtyNID(THash<TInt,TIntV >& CmtyVH, TRnd& Rnd) {

   THash<TInt,TIntV > NewCmtyVH(CmtyVH.Len());

   TIntV NDegV;

   TIntV CDegV;

   for (int i = 0; i < CmtyVH.Len(); i++) {

     int CID = CmtyVH.GetKey(i);

     for (int j = 0; j < CmtyVH[i].Len(); j++) {

       int NID = CmtyVH[i][j];

       NDegV.Add(NID);

       CDegV.Add(CID);

     }

   }

   TIntPrSet CNIDSet(CDegV.Len());

   int c=0;

   while (c++ < 15 && CDegV.Len() > 1){

     for (int i = 0; i < CDegV.Len(); i++) {

       int u = Rnd.GetUniDevInt(CDegV.Len());

       int v = Rnd.GetUniDevInt(NDegV.Len());

       if (CNIDSet.IsKey(TIntPr(CDegV[u], NDegV[v]))) { continue; }

       CNIDSet.AddKey(TIntPr(CDegV[u], NDegV[v]));

       if (u == CDegV.Len() - 1) {

         CDegV.DelLast();

       }  else {

         CDegV[u] = CDegV.Last();

         CDegV.DelLast();

       }

       if ( v == NDegV.Len() - 1) {

         NDegV.DelLast();

       }  else{

         NDegV[v] = NDegV.Last();

         NDegV.DelLast();

       }

     }

   }

   for (int i = 0; i < CNIDSet.Len(); i++) {

     TIntPr CNIDPr = CNIDSet[i];

     IAssert(CmtyVH.IsKey(CNIDPr.Val1));

     NewCmtyVH.AddDat(CNIDPr.Val1);

     NewCmtyVH.GetDat(CNIDPr.Val1).Add(CNIDPr.Val2);

   }

   CmtyVH = NewCmtyVH;

 }


 void TAGMUtil::LoadCmtyVV(const TStr& InFNm, TVec<TIntV>& CmtyVV) {

   CmtyVV.Gen(Kilo(100), 0);

   TSsParser Ss(InFNm, ssfWhiteSep);

   while (Ss.Next()) {

     if(Ss.GetFlds() > 0) {

       TIntV CmtyV;

       for (int i = 0; i < Ss.GetFlds(); i++) {

         if (Ss.IsInt(i)) {

           CmtyV.Add(Ss.GetInt(i));

         }

       }

       CmtyVV.Add(CmtyV);

     }

   }

   CmtyVV.Pack();

   printf("community loading completed (%d communities)\n",CmtyVV.Len());


 }


 void TAGMUtil::LoadCmtyVV(const TStr& InFNm, TVec<TIntV>& CmtyVV, TStrHash<TInt>& StrToNIdH, const int BeginCol, const int MinSz, const TSsFmt Sep) {

   CmtyVV.Gen(Kilo(100), 0);

   TSsParser Ss(InFNm, Sep);

   while (Ss.Next()) {

     if(Ss.GetFlds() > BeginCol) {

       TIntV CmtyV;

       for (int i = BeginCol; i < Ss.GetFlds(); i++) {

         if (StrToNIdH.IsKey(Ss.GetFld(i))) {

           CmtyV.Add(StrToNIdH.GetKeyId(Ss.GetFld(i)));

         }

       }

       if (CmtyV.Len() < MinSz) { continue; }

       CmtyVV.Add(CmtyV);

     }

   }

   CmtyVV.Pack();

   printf("community loading completed (%d communities)\n",CmtyVV.Len());

 }


 void TAGMUtil::DumpCmtyVV(const TStr& OutFNm, const TVec<TIntV>& CmtyVV) {

   FILE* F = fopen(OutFNm.CStr(),"wt");

   for (int i = 0; i < CmtyVV.Len(); i++) {

     for (int j = 0; j < CmtyVV[i].Len(); j++) {

       fprintf(F,"%d\t", (int) CmtyVV[i][j]);

     }

     fprintf(F,"\n");

   }

   fclose(F);

 }


 void TAGMUtil::DumpCmtyVV(const TStr OutFNm, TVec<TIntV>& CmtyVV, TIntStrH& NIDNmH) {

   FILE* F = fopen(OutFNm.CStr(), "wt");

   for (int c = 0; c < CmtyVV.Len(); c++) {

     for (int u = 0; u < CmtyVV[c].Len(); u++) {

       if (NIDNmH.IsKey(CmtyVV[c][u])){

         fprintf(F, "%s\t", NIDNmH.GetDat(CmtyVV[c][u]).CStr());

       }

       else {

         fprintf(F, "%d\t", (int) CmtyVV[c][u]);

       }

     }

     fprintf(F, "\n");

   }

   fclose(F);

 }


 int TAGMUtil::TotalMemberships(const TVec<TIntV>& CmtyVV){

   int M = 0;

   for (int i = 0; i < CmtyVV.Len(); i++) {

     M += CmtyVV[i].Len();

   }

   return M;

 }


 void TAGMUtil::GetNodeMembership(TIntH& NIDComVH, const THash<TInt,TIntV >& CmtyVH) {

   NIDComVH.Clr();

   for (THash<TInt,TIntV>::TIter HI = CmtyVH.BegI(); HI < CmtyVH.EndI(); HI++){

     for (int j = 0;j < HI.GetDat().Len(); j++) {

       int NID = HI.GetDat()[j];

       NIDComVH.AddDat(NID)++;

     }

   }

 }


 void TAGMUtil::GetNodeMembership(THash<TInt,TIntSet >& NIDComVH, const TVec<TIntV>& CmtyVV) {

   NIDComVH.Clr();

   for (int i = 0; i < CmtyVV.Len(); i++){

     int CID = i;

     for (int j = 0; j < CmtyVV[i].Len(); j++) {

       int NID = CmtyVV[i][j];

       NIDComVH.AddDat(NID).AddKey(CID);

     }

   }

 }


 void TAGMUtil::GetNodeMembership(THash<TInt,TIntSet >& NIDComVH, const TVec<TIntV>& CmtyVV, const TIntV& NIDV) {

   NIDComVH.Clr();

   for (int u = 0; u < NIDV.Len(); u++) {

     NIDComVH.AddDat(NIDV[u]);

   }

   for (int i = 0; i < CmtyVV.Len(); i++){

     int CID = i;

     for (int j = 0; j < CmtyVV[i].Len(); j++) {

       int NID = CmtyVV[i][j];

       NIDComVH.AddDat(NID).AddKey(CID);

     }

   }

 }


 void TAGMUtil::GetNodeMembership(THash<TInt,TIntSet >& NIDComVH, const TVec<TIntSet>& CmtyVV) {

   for (int i = 0; i < CmtyVV.Len(); i++){

     int CID = i;

     for (TIntSet::TIter SI = CmtyVV[i].BegI(); SI < CmtyVV[i].EndI(); SI++) {

       int NID = SI.GetKey();

       NIDComVH.AddDat(NID).AddKey(CID);

     }

   }

 }

 void TAGMUtil::GetNodeMembership(THash<TInt,TIntSet >& NIDComVH, const THash<TInt,TIntV>& CmtyVH) {

   for (THash<TInt,TIntV>::TIter HI = CmtyVH.BegI(); HI < CmtyVH.EndI(); HI++){

     int CID = HI.GetKey();

     for (int j = 0; j < HI.GetDat().Len(); j++) {

       int NID = HI.GetDat()[j];

       NIDComVH.AddDat(NID).AddKey(CID);

     }

   }

 }


 void TAGMUtil::GetNodeMembership(THash<TInt,TIntV >& NIDComVH, const THash<TInt,TIntV>& CmtyVH) {

   for (int i = 0; i < CmtyVH.Len(); i++){

     int CID = CmtyVH.GetKey(i);

     for (int j = 0; j < CmtyVH[i].Len(); j++) {

       int NID = CmtyVH[i][j];

       NIDComVH.AddDat(NID).Add(CID);

     }

   }

 }


 void TAGMUtil::GetNodeMembership(THash<TInt,TIntV >& NIDComVH, const TVec<TIntV>& CmtyVV) {

   THash<TInt,TIntV> CmtyVH;

   for (int i = 0; i < CmtyVV.Len(); i++) {

     CmtyVH.AddDat(i, CmtyVV[i]);

   }

   GetNodeMembership(NIDComVH, CmtyVH);

 }


 int TAGMUtil::Intersection(const TIntV& C1, const TIntV& C2) {

   TIntSet S1(C1), S2(C2);

   return TAGMUtil::Intersection(S1, S2);

 }


 void TAGMUtil::GetIntersection(const THashSet<TInt>& A, const THashSet<TInt>& B, THashSet<TInt>& C) {

   C.Gen(A.Len());

   if (A.Len() < B.Len()) {

     for (THashSetKeyI<TInt> it = A.BegI(); it < A.EndI(); it++)

       if (B.IsKey(it.GetKey())) C.AddKey(it.GetKey());

   } else {

     for (THashSetKeyI<TInt> it = B.BegI(); it < B.EndI(); it++)

       if (A.IsKey(it.GetKey())) C.AddKey(it.GetKey());

   }

 }


 int TAGMUtil::Intersection(const THashSet<TInt>& A, const THashSet<TInt>& B) {

   int n = 0;

   if (A.Len() < B.Len()) {

     for (THashSetKeyI<TInt> it = A.BegI(); it < A.EndI(); it++)

       if (B.IsKey(it.GetKey())) n++;

   } else {

     for (THashSetKeyI<TInt> it = B.BegI(); it < B.EndI(); it++)

       if (A.IsKey(it.GetKey())) n++;

   }

   return n;

 }


 void TAGMUtil::SaveGephi(const TStr& OutFNm, const PUNGraph& G, const TVec<TIntV>& CmtyVVAtr, const double MaxSz, const double MinSz, const TIntStrH& NIDNameH, const THash<TInt, TIntTr>& NIDColorH ) {

   THash<TInt,TIntV> NIDComVHAtr;

   TAGMUtil::GetNodeMembership(NIDComVHAtr, CmtyVVAtr);


   FILE* F = fopen(OutFNm.CStr(), "wt");

   fprintf(F, "<?xml version='1.0' encoding='UTF-8'?>\n");

   fprintf(F, "<gexf xmlns='http://www.gexf.net/1.2draft' xmlns:viz='http://www.gexf.net/1.1draft/viz' xmlns:xsi='http://www.w3.org/2001/XMLSchema-instance' xsi:schemaLocation='http://www.gexf.net/1.2draft http://www.gexf.net/1.2draft/gexf.xsd' version='1.2'>\n");

   fprintf(F, "\t<graph mode='static' defaultedgetype='undirected'>\n");

   if (CmtyVVAtr.Len() > 0) {

     fprintf(F, "\t<attributes class='node'>\n");

     for (int c = 0; c < CmtyVVAtr.Len(); c++) {

       fprintf(F, "\t\t<attribute id='%d' title='c%d' type='boolean'>", c, c);

       fprintf(F, "\t\t<default>false</default>\n");

       fprintf(F, "\t\t</attribute>\n");

     }

     fprintf(F, "\t</attributes>\n");

   }

   fprintf(F, "\t\t<nodes>\n");

   for (TUNGraph::TNodeI NI = G->BegNI(); NI < G->EndNI(); NI++) {

     int NID = NI.GetId();

     TStr Label = NIDNameH.IsKey(NID)? NIDNameH.GetDat(NID): "";

     TIntTr Color = NIDColorH.IsKey(NID)? NIDColorH.GetDat(NID) : TIntTr(120, 120, 120);


     double Size = MinSz;

     double SizeStep = (MaxSz - MinSz) / (double) CmtyVVAtr.Len();

     if (NIDComVHAtr.IsKey(NID)) {

       Size = MinSz +  SizeStep *  (double) NIDComVHAtr.GetDat(NID).Len();

     }

     double Alpha = 1.0;

     fprintf(F, "\t\t\t<node id='%d' label='%s'>\n", NID, Label.CStr());

     fprintf(F, "\t\t\t\t<viz:color r='%d' g='%d' b='%d' a='%.1f'/>\n", Color.Val1.Val, Color.Val2.Val, Color.Val3.Val, Alpha);

     fprintf(F, "\t\t\t\t<viz:size value='%.3f'/>\n", Size);

     //specify attributes

     if (NIDComVHAtr.IsKey(NID)) {

       fprintf(F, "\t\t\t\t<attvalues>\n");

       for (int c = 0; c < NIDComVHAtr.GetDat(NID).Len(); c++) {

         int CID = NIDComVHAtr.GetDat(NID)[c];

         fprintf(F, "\t\t\t\t\t<attvalue for='%d' value='true'/>\n", CID);

       }

       fprintf(F, "\t\t\t\t</attvalues>\n");

     }


     fprintf(F, "\t\t\t</node>\n");

   }

   fprintf(F, "\t\t</nodes>\n");

   //plot edges

   int EID = 0;

   fprintf(F, "\t\t<edges>\n");

   for (TUNGraph::TEdgeI EI = G->BegEI(); EI < G->EndEI(); EI++) {

     fprintf(F, "\t\t\t<edge id='%d' source='%d' target='%d'/>\n", EID++, EI.GetSrcNId(), EI.GetDstNId());

   }

   fprintf(F, "\t\t</edges>\n");

   fprintf(F, "\t</graph>\n");

   fprintf(F, "</gexf>\n");

   fclose(F);

 }


 void TAGMUtil::SaveBipartiteGephi(const TStr& OutFNm, const TIntV& NIDV, const TVec<TIntV>& CmtyVV, const double MaxSz, const double MinSz, const TIntStrH& NIDNameH, const THash<TInt, TIntTr>& NIDColorH, const THash<TInt, TIntTr>& CIDColorH ) {

   if (CmtyVV.Len() == 0) { return; }

   double NXMin = 0.1, YMin = 0.1, NXMax = 250.00, YMax = 30.0;

   double CXMin = 0.3 * NXMax, CXMax = 0.7 * NXMax;

   double CStep = (CXMax - CXMin) / (double) CmtyVV.Len(), NStep = (NXMax - NXMin) / (double) NIDV.Len();

   THash<TInt,TIntV> NIDComVH;

   TAGMUtil::GetNodeMembership(NIDComVH, CmtyVV);


   FILE* F = fopen(OutFNm.CStr(), "wt");

   fprintf(F, "<?xml version='1.0' encoding='UTF-8'?>\n");

   fprintf(F, "<gexf xmlns='http://www.gexf.net/1.2draft' xmlns:viz='http://www.gexf.net/1.1draft/viz' xmlns:xsi='http://www.w3.org/2001/XMLSchema-instance' xsi:schemaLocation='http://www.gexf.net/1.2draft http://www.gexf.net/1.2draft/gexf.xsd' version='1.2'>\n");

   fprintf(F, "\t<graph mode='static' defaultedgetype='directed'>\n");

   fprintf(F, "\t\t<nodes>\n");

   for (int c = 0; c < CmtyVV.Len(); c++) {

     int CID = c;

     double XPos = c * CStep + CXMin;

     TIntTr Color = CIDColorH.IsKey(CID)? CIDColorH.GetDat(CID) : TIntTr(120, 120, 120);

     fprintf(F, "\t\t\t<node id='C%d' label='C%d'>\n", CID, CID);

     fprintf(F, "\t\t\t\t<viz:color r='%d' g='%d' b='%d'/>\n", Color.Val1.Val, Color.Val2.Val, Color.Val3.Val);

     fprintf(F, "\t\t\t\t<viz:size value='%.3f'/>\n", MaxSz);

     fprintf(F, "\t\t\t\t<viz:shape value='square'/>\n");

     fprintf(F, "\t\t\t\t<viz:position x='%f' y='%f' z='0.0'/>\n", XPos, YMax);

     fprintf(F, "\t\t\t</node>\n");

   }


   for (int u = 0;u < NIDV.Len(); u++) {

     int NID = NIDV[u];

     TStr Label = NIDNameH.IsKey(NID)? NIDNameH.GetDat(NID): "";

     double Size = MinSz;

     double XPos = NXMin + u * NStep;

     TIntTr Color = NIDColorH.IsKey(NID)? NIDColorH.GetDat(NID) : TIntTr(120, 120, 120);

     double Alpha = 1.0;

     fprintf(F, "\t\t\t<node id='%d' label='%s'>\n", NID, Label.CStr());

     fprintf(F, "\t\t\t\t<viz:color r='%d' g='%d' b='%d' a='%.1f'/>\n", Color.Val1.Val, Color.Val2.Val, Color.Val3.Val, Alpha);

     fprintf(F, "\t\t\t\t<viz:size value='%.3f'/>\n", Size);

     fprintf(F, "\t\t\t\t<viz:shape value='square'/>\n");

     fprintf(F, "\t\t\t\t<viz:position x='%f' y='%f' z='0.0'/>\n", XPos, YMin);

     fprintf(F, "\t\t\t</node>\n");

   }

   fprintf(F, "\t\t</nodes>\n");

   fprintf(F, "\t\t<edges>\n");

   int EID = 0;

   for (int u = 0;u < NIDV.Len(); u++) {

     int NID = NIDV[u];

     if (NIDComVH.IsKey(NID)) {

       for (int c = 0; c < NIDComVH.GetDat(NID).Len(); c++) {

         int CID = NIDComVH.GetDat(NID)[c];

         fprintf(F, "\t\t\t<edge id='%d' source='C%d' target='%d'/>\n", EID++, CID, NID);

       }

     }

   }

   fprintf(F, "\t\t</edges>\n");

   fprintf(F, "\t</graph>\n");

   fprintf(F, "</gexf>\n");

 }


 int TAGMUtil::FindComsByAGM(const PUNGraph& Graph, const int InitComs, const int MaxIter, const int RndSeed, const double RegGap, const double PNoCom, const TStr PltFPrx) {

   TRnd Rnd(RndSeed);

   int LambdaIter = 100;

   if (Graph->GetNodes() < 200) { LambdaIter = 1; }

   if (Graph->GetNodes() < 200 && Graph->GetEdges() > 2000) { LambdaIter = 100; }


   //Find coms with large C

   TAGMFit AGMFitM(Graph, InitComs, RndSeed);

   if (PNoCom > 0.0) { AGMFitM.SetPNoCom(PNoCom); }

   AGMFitM.RunMCMC(MaxIter, LambdaIter, "");


   int TE = Graph->GetEdges();

   TFltV RegV;

   RegV.Add(0.3 * TE);

   for (int r = 0; r < 25; r++) {

     RegV.Add(RegV.Last() * RegGap);

   }

   TFltPrV RegComsV, RegLV, RegBICV;

   TFltV LV, BICV;

   //record likelihood and number of communities with nonzero P_c

   for (int r = 0; r < RegV.Len(); r++) {

     double RegCoef = RegV[r];

     AGMFitM.SetRegCoef(RegCoef);

     AGMFitM.MLEGradAscentGivenCAG(0.01, 1000);

     AGMFitM.SetRegCoef(0.0);


     TVec<TIntV> EstCmtyVV;

     AGMFitM.GetCmtyVV(EstCmtyVV, 0.99);

     int NumLowQ = EstCmtyVV.Len();

     RegComsV.Add(TFltPr(RegCoef, (double) NumLowQ));


     if (EstCmtyVV.Len() > 0) {

       TAGMFit AFTemp(Graph, EstCmtyVV, Rnd);

       AFTemp.MLEGradAscentGivenCAG(0.001, 1000);

       double CurL = AFTemp.Likelihood();

       LV.Add(CurL);

       BICV.Add(-2.0 * CurL + (double) EstCmtyVV.Len() * log((double) Graph->GetNodes() * (Graph->GetNodes() - 1) / 2.0));

     }

     else {

       break;

     }

   }

   // if likelihood does not exist or does not change at all, report the smallest number of communities or 2

   if (LV.Len() == 0) { return 2; }

   else if (LV[0] == LV.Last()) { return (int) TMath::Mx<TFlt>(2.0, RegComsV[LV.Len() - 1].Val2); }


   //normalize likelihood and BIC to 0~100

   int MaxL = 100;

   {

     TFltV& ValueV = LV;

     TFltPrV& RegValueV = RegLV;

     double MinValue = TFlt::Mx, MaxValue = TFlt::Mn;

     for (int l = 0; l < ValueV.Len(); l++) {

       if (ValueV[l] < MinValue) { MinValue = ValueV[l]; }

       if (ValueV[l] > MaxValue) { MaxValue = ValueV[l]; }

     }

     while (ValueV.Len() < RegV.Len()) { ValueV.Add(MinValue); }

     double RangeVal = MaxValue - MinValue;

     for (int l = 0; l < ValueV.Len(); l++) {

       RegValueV.Add(TFltPr(RegV[l], double(MaxL) * (ValueV[l] - MinValue) / RangeVal));

     }


   }

   {

     TFltV& ValueV = BICV;

     TFltPrV& RegValueV = RegBICV;

     double MinValue = TFlt::Mx, MaxValue = TFlt::Mn;

     for (int l = 0; l < ValueV.Len(); l++) {

       if (ValueV[l] < MinValue) { MinValue = ValueV[l]; }

       if (ValueV[l] > MaxValue) { MaxValue = ValueV[l]; }

     }

     while (ValueV.Len() < RegV.Len()) { ValueV.Add(MaxValue); }

     double RangeVal = MaxValue - MinValue;

     for (int l = 0; l < ValueV.Len(); l++) {

       RegValueV.Add(TFltPr(RegV[l], double(MaxL) * (ValueV[l] - MinValue) / RangeVal));

     }

   }


   //fit logistic regression to normalized likelihood.

   TVec<TFltV> XV(RegLV.Len());

   TFltV YV (RegLV.Len());

   for (int l = 0; l < RegLV.Len(); l++) {

     XV[l] = TFltV::GetV(log(RegLV[l].Val1));

     YV[l] = RegLV[l].Val2 / (double) MaxL;

   }

   TFltPrV LRVScaled, LRV;

   TLogRegFit LRFit;

   PLogRegPredict LRMd = LRFit.CalcLogRegNewton(XV, YV, PltFPrx);

   for (int l = 0; l < RegLV.Len(); l++) {

     LRV.Add(TFltPr(RegV[l], LRMd->GetCfy(XV[l])));

     LRVScaled.Add(TFltPr(RegV[l], double(MaxL) * LRV.Last().Val2));

   }


   //estimate # communities from fitted logistic regression

   int NumComs = 0, IdxRegDrop = 0;

   double LRThres = 1.1, RegDrop; // 1 / (1 + exp(1.1)) = 0.25

   double LeftReg = 0.0, RightReg = 0.0;

   TFltV Theta;

   LRMd->GetTheta(Theta);

   RegDrop = (- Theta[1] - LRThres) / Theta[0];

   if (RegDrop <= XV[0][0]) { NumComs = (int) RegComsV[0].Val2; }

   else if (RegDrop >= XV.Last()[0]) { NumComs = (int) RegComsV.Last().Val2; }

   else {  //interpolate for RegDrop

     for (int i = 0; i < XV.Len(); i++) {

       if (XV[i][0] > RegDrop) { IdxRegDrop = i; break; }

     }


     if (IdxRegDrop == 0) {

       printf("Error!! RegDrop:%f, Theta[0]:%f, Theta[1]:%f\n", RegDrop, Theta[0].Val, Theta[1].Val);

       for (int l = 0; l < RegLV.Len(); l++) {

         printf("X[%d]:%f, Y[%d]:%f\n", l, XV[l][0].Val, l, YV[l].Val);

       }

     }

     IAssert(IdxRegDrop > 0);

     LeftReg = RegDrop - XV[IdxRegDrop - 1][0];

     RightReg = XV[IdxRegDrop][0] - RegDrop;

     NumComs = (int) TMath::Round( (RightReg * RegComsV[IdxRegDrop - 1].Val2 + LeftReg * RegComsV[IdxRegDrop].Val2) / (LeftReg + RightReg));


   }

   //printf("Interpolation coeff: %f, %f, index at drop:%d (%f), Left-Right Vals: %f, %f\n", LeftReg, RightReg, IdxRegDrop, RegDrop, RegComsV[IdxRegDrop - 1].Val2, RegComsV[IdxRegDrop].Val2);

   printf("Num Coms:%d\n", NumComs);

   if (NumComs < 2) { NumComs = 2; }


   if (PltFPrx.Len() > 0) {

     TStr PlotTitle = TStr::Fmt("N:%d, E:%d ", Graph->GetNodes(), TE);

     TGnuPlot GPC(PltFPrx + ".l");

     GPC.AddPlot(RegComsV, gpwLinesPoints, "C");

     GPC.AddPlot(RegLV, gpwLinesPoints, "likelihood");

     GPC.AddPlot(RegBICV, gpwLinesPoints, "BIC");

     GPC.AddPlot(LRVScaled, gpwLinesPoints, "Sigmoid (scaled)");

     GPC.SetScale(gpsLog10X);

     GPC.SetTitle(PlotTitle);

     GPC.SavePng(PltFPrx + ".l.png");

   }


   return NumComs;

 }


 double TAGMUtil::GetConductance(const PUNGraph& Graph, const TIntSet& CmtyS, const int Edges) {

   const int Edges2 = Edges >= 0 ? 2*Edges : Graph->GetEdges();

   int Vol = 0,  Cut = 0;

   double Phi = 0.0;

   for (int i = 0; i < CmtyS.Len(); i++) {

     if (! Graph->IsNode(CmtyS[i])) { continue; }

     TUNGraph::TNodeI NI = Graph->GetNI(CmtyS[i]);

     for (int e = 0; e < NI.GetOutDeg(); e++) {

       if (! CmtyS.IsKey(NI.GetOutNId(e))) { Cut += 1; }

     }

     Vol += NI.GetOutDeg();

   }

   // get conductance

   if (Vol != Edges2) {

     if (2 * Vol > Edges2) { Phi = Cut / double (Edges2 - Vol); }

     else if (Vol == 0) { Phi = 0.0; }

     else { Phi = Cut / double(Vol); }

   } else {

     if (Vol == Edges2) { Phi = 1.0; }

   }

   return Phi;

 }


 void TAGMUtil::GetNbhCom(const PUNGraph& Graph, const int NID, TIntSet& NBCmtyS) {

   TUNGraph::TNodeI NI = Graph->GetNI(NID);

   NBCmtyS.Gen(NI.GetDeg());

   NBCmtyS.AddKey(NID);

   for (int e = 0; e < NI.GetDeg(); e++) {

     NBCmtyS.AddKey(NI.GetNbrNId(e));

   }

 }


 // Logistic regression by gradient ascent


 void TLogRegFit::GetNewtonStep(TFltVV& HVV, const TFltV& GradV, TFltV& DeltaLV){

   bool HSingular = false;

   for (int i = 0; i < HVV.GetXDim(); i++) {

     if (HVV(i,i) == 0.0) {

       HVV(i,i) = 0.001;

       HSingular = true;

     }

     DeltaLV[i] = GradV[i] / HVV(i, i);

   }

   if (! HSingular) {

     if (HVV(0, 0) < 0) { // if Hessian is negative definite, convert it to positive definite

       for (int r = 0; r < Theta.Len(); r++) {

         for (int c = 0; c < Theta.Len(); c++) {

           HVV(r, c) = - HVV(r, c);

         }

       }

       TNumericalStuff::SolveSymetricSystem(HVV, GradV, DeltaLV);

     }

     else {

       TNumericalStuff::SolveSymetricSystem(HVV, GradV, DeltaLV);

       for (int i = 0; i < DeltaLV.Len(); i++) {

         DeltaLV[i] = - DeltaLV[i];

       }

     }


   }

 }


 void TLogRegFit::Hessian(TFltVV& HVV) {

   HVV.Gen(Theta.Len(), Theta.Len());

   TFltV OutV;

   TLogRegPredict::GetCfy(X, OutV, Theta);

   for (int i = 0; i < X.Len(); i++) {

     for (int r = 0; r < Theta.Len(); r++) {

       HVV.At(r, r) += - (X[i][r] * OutV[i] * (1 - OutV[i]) * X[i][r]);

       for (int c = r + 1; c < Theta.Len(); c++) {

         HVV.At(r, c) += - (X[i][r] * OutV[i] * (1 - OutV[i]) * X[i][c]);

         HVV.At(c, r) += - (X[i][r] * OutV[i] * (1 - OutV[i]) * X[i][c]);

       }

     }

   }

   /*

   printf("\n");

   for (int r = 0; r < Theta.Len(); r++) {

     for (int c = 0; c < Theta.Len(); c++) {

       printf("%f\t", HVV.At(r, c).Val);

     }

     printf("\n");

   }

   */

 }


 int TLogRegFit::MLENewton(const double& ChangeEps, const int& MaxStep, const TStr PlotNm) {

   TExeTm ExeTm;

   TFltV GradV(Theta.Len()), DeltaLV(Theta.Len());

   TFltVV HVV(Theta.Len(), Theta.Len());

   int iter = 0;

   double MinVal = -1e10, MaxVal = 1e10;

   for(iter = 0; iter < MaxStep; iter++) {

     Gradient(GradV);

     Hessian(HVV);

     GetNewtonStep(HVV, GradV, DeltaLV);

     double Increment = TLinAlg::DotProduct(GradV, DeltaLV);

     if (Increment <= ChangeEps) {break;}

     double LearnRate = GetStepSizeByLineSearch(DeltaLV, GradV, 0.15, 0.5);//InitLearnRate/double(0.01*(double)iter + 1);

     for(int i = 0; i < Theta.Len(); i++) {

       double Change = LearnRate * DeltaLV[i];

       Theta[i] += Change;

       if(Theta[i] < MinVal) { Theta[i] = MinVal;}

       if(Theta[i] > MaxVal) { Theta[i] = MaxVal;}

     }

   }

   if (! PlotNm.Empty()) {

     printf("MLE with Newton method completed with %d iterations(%s)\n",iter,ExeTm.GetTmStr());

   }


   return iter;

 }


 int TLogRegFit::MLEGradient(const double& ChangeEps, const int& MaxStep, const TStr PlotNm) {

   TExeTm ExeTm;

   TFltV GradV(Theta.Len());

   int iter = 0;

   TIntFltPrV IterLV, IterGradNormV;

   double MinVal = -1e10, MaxVal = 1e10;

   double GradCutOff = 100000;

   for(iter = 0; iter < MaxStep; iter++) {

     Gradient(GradV);    //if gradient is going out of the boundary, cut off

     for(int i = 0; i < Theta.Len(); i++) {

       if (GradV[i] < -GradCutOff) { GradV[i] = -GradCutOff; }

       if (GradV[i] > GradCutOff) { GradV[i] = GradCutOff; }

       if (Theta[i] <= MinVal && GradV[i] < 0) { GradV[i] = 0.0; }

       if (Theta[i] >= MaxVal && GradV[i] > 0) { GradV[i] = 0.0; }

     }

     double Alpha = 0.15, Beta = 0.9;

     //double LearnRate = 0.1 / (0.1 * iter + 1); //GetStepSizeByLineSearch(GradV, GradV, Alpha, Beta);

     double LearnRate = GetStepSizeByLineSearch(GradV, GradV, Alpha, Beta);

     if (TLinAlg::Norm(GradV) < ChangeEps) { break; }

     for(int i = 0; i < Theta.Len(); i++) {

       double Change = LearnRate * GradV[i];

       Theta[i] += Change;

       if(Theta[i] < MinVal) { Theta[i] = MinVal;}

       if(Theta[i] > MaxVal) { Theta[i] = MaxVal;}

     }

     if (! PlotNm.Empty()) {

       double L = Likelihood();

       IterLV.Add(TIntFltPr(iter, L));

       IterGradNormV.Add(TIntFltPr(iter, TLinAlg::Norm(GradV)));

     }


   }

   if (! PlotNm.Empty()) {

     TGnuPlot::PlotValV(IterLV, PlotNm + ".likelihood_Q");

     TGnuPlot::PlotValV(IterGradNormV, PlotNm + ".gradnorm_Q");

     printf("MLE for Lambda completed with %d iterations(%s)\n",iter,ExeTm.GetTmStr());

   }

   return iter;

 }


 double TLogRegFit::GetStepSizeByLineSearch(const TFltV& DeltaV, const TFltV& GradV, const double& Alpha, const double& Beta) {

   double StepSize = 1.0;

   double InitLikelihood = Likelihood();

   IAssert(Theta.Len() == DeltaV.Len());

   TFltV NewThetaV(Theta.Len());

   double MinVal = -1e10, MaxVal = 1e10;

   for(int iter = 0; ; iter++) {

     for (int i = 0; i < Theta.Len(); i++){

       NewThetaV[i] = Theta[i] + StepSize * DeltaV[i];

       if (NewThetaV[i] < MinVal) { NewThetaV[i] = MinVal;  }

       if (NewThetaV[i] > MaxVal) { NewThetaV[i] = MaxVal; }

     }

     if (Likelihood(NewThetaV) < InitLikelihood + Alpha * StepSize * TLinAlg::DotProduct(GradV, DeltaV)) {

       StepSize *= Beta;

     } else {

       break;

     }

   }

   return StepSize;

 }


 double TLogRegFit::Likelihood(const TFltV& NewTheta) {

   TFltV OutV;

   TLogRegPredict::GetCfy(X, OutV, NewTheta);

   double L = 0;

   for (int r = 0; r < OutV.Len(); r++) {

     L += Y[r] * log(OutV[r]);

     L += (1 - Y[r]) * log(1 - OutV[r]);

   }

   return L;

 }


 void TLogRegFit::Gradient(TFltV& GradV) {

   TFltV OutV;

   TLogRegPredict::GetCfy(X, OutV, Theta);

   GradV.Gen(M);

   for (int r = 0; r < X.Len(); r++) {

     //printf("Y[%d] = %f, Out[%d] = %f\n", r, Y[r].Val, r, OutV[r].Val);

     for (int m = 0; m < M; m++) {

       GradV[m] += (Y[r] - OutV[r]) * X[r][m];

     }

   }

   //for (int m = 0; m < M; m++) {  printf("Theta[%d] = %f, GradV[%d] = %f\n", m, Theta[m].Val, m, GradV[m].Val); }

 }


 PLogRegPredict TLogRegFit::CalcLogRegNewton(const TVec<TFltV>& XPt, const TFltV& yPt, const TStr& PlotNm, const double& ChangeEps, const int& MaxStep, const bool Intercept) {


   X = XPt;

   Y = yPt;

   IAssert(X.Len() == Y.Len());

   if (Intercept == false) { // if intercept is not included, add it

     for (int r = 0; r < X.Len(); r++) {  X[r].Add(1); }

   }

   M = X[0].Len();

   for (int r = 0; r < X.Len(); r++) {  IAssert(X[r].Len() == M); }

   for (int r = 0; r < Y.Len(); r++) {

     if (Y[r] >= 0.99999) { Y[r] = 0.99999; }

     if (Y[r] <= 0.00001) { Y[r] = 0.00001; }

   }

   Theta.Gen(M);

   MLENewton(ChangeEps, MaxStep, PlotNm);

   return new TLogRegPredict(Theta);

 };


 PLogRegPredict TLogRegFit::CalcLogRegGradient(const TVec<TFltV>& XPt, const TFltV& yPt, const TStr& PlotNm, const double& ChangeEps, const int& MaxStep, const bool Intercept) {

   X = XPt;

   Y = yPt;

   IAssert(X.Len() == Y.Len());

   if (Intercept == false) { // if intercept is not included, add it

     for (int r = 0; r < X.Len(); r++) {  X[r].Add(1); }

   }

   M = X[0].Len();

   for (int r = 0; r < X.Len(); r++) {  IAssert(X[r].Len() == M); }

   for (int r = 0; r < Y.Len(); r++) {

     if (Y[r] >= 0.99999) { Y[r] = 0.99999; }

     if (Y[r] <= 0.00001) { Y[r] = 0.00001; }

   }

   Theta.Gen(M);

   MLEGradient(ChangeEps, MaxStep, PlotNm);

   return new TLogRegPredict(Theta);

 };


 // Logistic-Regression-Model


 double TLogRegPredict::GetCfy(const TFltV& AttrV, const TFltV& NewTheta) {

     int len = AttrV.Len();

     double res = 0;

     if (len < NewTheta.Len()) { res = NewTheta.Last(); } //if feature vector is shorter, add an intercept

     for (int i = 0; i < len; i++) {

       if (i < NewTheta.Len()) { res += AttrV[i] * NewTheta[i]; }

     }

     double mu = 1 / (1 + exp(-res));

     return mu;

 }


 void TLogRegPredict::GetCfy(const TVec<TFltV>& X, TFltV& OutV, const TFltV& NewTheta) {

   OutV.Gen(X.Len());

   for (int r = 0; r < X.Len(); r++) {

     OutV[r] = GetCfy(X[r], NewTheta);

   }

 }

TLogRegFit::X
TVec< TFltV > X
Definition: agm.h:169

IAssert
#define IAssert(Cond)
Definition: bd.h:262

TUNGraph::TEdgeI
Edge iterator. Only forward iteration (operator++) is supported.
Definition: graph.h:117

TIntPr
TPair< TInt, TInt > TIntPr
Definition: ds.h:83

TAGMUtil::GetNbhCom
static void GetNbhCom(const PUNGraph &Graph, const int NID, TIntSet &NBCmtyS)
Definition: agm.cpp:706

TVec::EndI
TIter EndI() const
Returns an iterator referring to the past-the-end element in the vector.
Definition: ds.h:567

TLogRegFit::GetNewtonStep
void GetNewtonStep(TFltVV &HVV, const TFltV &GradV, TFltV &DeltaLV)
Definition: agm.cpp:718

TLinAlg::Norm
static double Norm(const TFltV &x)
Definition: linalg.cpp:324

Snap.h

TStr::Len
int Len() const
Definition: dt.h:487

TAGMUtil::TotalMemberships
static int TotalMemberships(const TVec< TIntV > &CmtyVV)
total number of memberships (== sum of the sizes of communities)
Definition: agm.cpp:315

THash::GetDatV
void GetDatV(TVec< TDat > &DatV) const
Definition: hash.h:450

TUNGraph::EndEI
TEdgeI EndEI() const
Returns an iterator referring to the past-the-end edge in the graph.
Definition: graph.h:241

TExeTm
Definition: tm.h:355

TAGMUtil::RewireCmtyVV
static void RewireCmtyVV(const TVec< TIntV > &CmtyVVIn, TVec< TIntV > &CmtyVVOut, TRnd &Rnd)
rewire bipartite community affiliation graphs
Definition: agm.cpp:192

Kilo
#define Kilo(n)
Definition: gbase.h:3

TRnd
Definition: dt.h:11

TAGMUtil::GetNodeMembership
static void GetNodeMembership(THash< TInt, TIntSet > &NIDComVH, const TVec< TIntV > &CmtyVV)
get hash table of
Definition: agm.cpp:335

TTriple
Definition: ds.h:129

TLogRegPredict::GetCfy
static void GetCfy(const TVec< TFltV > &X, TFltV &OutV, const TFltV &NewTheta)
Definition: agm.cpp:933

TAGMFit::SetPNoCom
void SetPNoCom(const double &Epsilon)
Set Epsilon (the probability that two nodes sharing no communities connect) to the default value...
Definition: agmfit.h:57

THashSet::BegI
TIter BegI() const
Definition: shash.h:1105

TUNGraph::GetNIdV
void GetNIdV(TIntV &NIdV) const
Gets a vector IDs of all nodes in the graph.
Definition: graph.cpp:153

agmfit.h

THash::BegI
TIter BegI() const
Definition: hash.h:171

TUNGraph::AddNode
int AddNode(int NId=-1)
Adds a node of ID NId to the graph.
Definition: graph.cpp:8

TAGMFit::Likelihood
double Likelihood()
COMMENT.
Definition: agmfit.cpp:104

TAGMUtil::GenPLSeq
static void GenPLSeq(TIntV &SzSeq, const int &SeqLen, const double &Alpha, TRnd &Rnd, const int &Min, const int &Max)
AGMUtil:: Utilities for AGM.
Definition: agm.cpp:81

TUNGraph::GetEdges
int GetEdges() const
Returns the number of edges in the graph.
Definition: graph.cpp:82

TVec::Len
TSizeTy Len() const
Returns the number of elements in the vector.
Definition: ds.h:547

TUNGraph::TNodeI
Node iterator. Only forward iteration (operator++) is supported.
Definition: graph.h:64

TAGMUtil::Intersection
static int Intersection(const TIntV &C1, const TIntV &C2)
Definition: agm.cpp:399

THashSet::GetKeyV
void GetKeyV(TVec< TKey > &KeyV) const
Definition: shash.h:1347

TSsParser
Definition: ss.h:72

THashSet::Gen
void Gen(const int &ExpectVals)
Definition: shash.h:1115

TLogRegFit::Likelihood
double Likelihood()
Definition: agm.h:183

gpwLinesPoints
Definition: gnuplot.h:12

TVVec::GetXDim
int GetXDim() const
Definition: ds.h:2184

TTriple::Val1
TVal1 Val1
Definition: ds.h:131

TSsParser::GetInt
bool GetInt(const int &FldN, int &Val) const
If the field FldN is an integer its value is returned in Val and the function returns true...
Definition: ss.cpp:447

THash::GetDat
const TDat & GetDat(const TKey &Key) const
Definition: hash.h:220

TAGMUtil::GetIntersection
static void GetIntersection(const THashSet< TInt > &A, const THashSet< TInt > &B, THashSet< TInt > &C)
Definition: agm.cpp:404

THash::EndI
TIter EndI() const
Definition: hash.h:176

TAGMFit
Fitting the Affilialiton Graph Model (AGM).
Definition: agmfit.h:8

TAGMUtil::GetConductance
static double GetConductance(const PUNGraph &Graph, const TIntSet &CmtyS, const int Edges)
Definition: agm.cpp:683

TSsParser::GetFlds
int GetFlds() const
Returns the number of fields in the current line.
Definition: ss.h:116

TFlt::Mx
static const double Mx
Definition: dt.h:1298

THashSet::IsKey
bool IsKey(const TKey &Key) const
Definition: shash.h:1148

TUNGraph::GetNodes
int GetNodes() const
Returns the number of nodes in the graph.
Definition: graph.h:168

TSsParser::GetFld
const char * GetFld(const int &FldN) const
Returns the contents of the field at index FldN.
Definition: ss.h:129

edge
Definition: motifcluster.h:34

TLogRegFit::Y
TFltV Y
Definition: agm.h:170

TSsFmt
TSsFmt
Spread-Sheet Separator Format.
Definition: ss.h:5

TIntFltPr
TPair< TInt, TFlt > TIntFltPr
Definition: ds.h:87

TUNGraph::TNodeI::GetDeg
int GetDeg() const
Returns degree of the current node.
Definition: graph.h:86

TExeTm::GetTmStr
const char * GetTmStr() const
Definition: tm.h:370

TAGMUtil::SaveGephi
static void SaveGephi(const TStr &OutFNm, const PUNGraph &G, const TVec< TIntV > &CmtyVVAtr, const double MaxSz, const double MinSz)
Definition: agm.h:55

THashSet
Definition: shash.h:1047

TAGMUtil::ConnectCmtyVV
static void ConnectCmtyVV(TVec< TIntV > &CmtyVV, const TIntPrV &CIDSzPrV, const TIntPrV &NIDMemPrV, TRnd &Rnd)
Generate bipartite community affiliation from given power law coefficients for membership distributio...
Definition: agm.cpp:131

TTriple::Val2
TVal2 Val2
Definition: ds.h:132

TUNGraph::TNodeI::GetOutDeg
int GetOutDeg() const
Returns out-degree of the current node (returns same as value GetDeg() since the graph is undirected)...
Definition: graph.h:90

TVec::Clr
void Clr(const bool &DoDel=true, const TSizeTy &NoDelLim=-1)
Clears the contents of the vector.
Definition: ds.h:971

TAGMFit::GetCmtyVV
void GetCmtyVV(TVec< TIntV > &CmtyVV, const double QMax=2.0)
Get communities whose  p_c is higher than 1 - QMax.
Definition: agmfit.cpp:554

TAGMFit::MLEGradAscentGivenCAG
int MLEGradAscentGivenCAG(const double &Thres=0.001, const int &MaxIter=10000, const TStr PlotNm=TStr())
Gradient descent for p_c while keeping the community affiliation graph (CAG) fixed.
Definition: agmfit.cpp:130

TStrHash::IsKey
bool IsKey(const char *Key) const
Definition: hash.h:825

TLogRegFit::Theta
TFltV Theta
Definition: agm.h:171

TVVec< TFlt >

TLogRegFit::Hessian
void Hessian(TFltVV &HVV)
Definition: agm.cpp:746

TLogRegFit::CalcLogRegNewton
PLogRegPredict CalcLogRegNewton(const TVec< TFltV > &XPt, const TFltV &yPt, const TStr &PlotNm=TStr(), const double &ChangeEps=0.01, const int &MaxStep=200, const bool InterceptPt=false)
Definition: agm.cpp:882

TAGMUtil::GenCmtyVVFromPL
static void GenCmtyVVFromPL(TVec< TIntV > &CmtyVV, const PUNGraph &Graph, const int &Nodes, const int &Coms, const double &ComSzAlpha, const double &MemAlpha, const int &MinSz, const int &MaxSz, const int &MinK, const int &MaxK, TRnd &Rnd)
Generate bipartite community affiliation from given power law coefficients for membership distributio...
Definition: agm.cpp:101

TMath::Round
static double Round(const double &Val)
Definition: xmath.h:16

ssfWhiteSep
Whitespace (space or tab) separated.
Definition: ss.h:11

TUNGraph::GetNI
TNodeI GetNI(const int &NId) const
Returns an iterator referring to the node of ID NId in the graph.
Definition: graph.h:213

TLogRegFit::M
int M
Definition: agm.h:172

TAGMFit::SetRegCoef
void SetRegCoef(const double Val)
Definition: agmfit.h:45

TUNGraph::BegEI
TEdgeI BegEI() const
Returns an iterator referring to the first edge in the graph.
Definition: graph.h:239

TUNGraph::New
static PUNGraph New()
Static constructor that returns a pointer to the graph. Call: PUNGraph Graph = TUNGraph::New().
Definition: graph.h:155

THashSet::AddKey
int AddKey(const TKey &Key)
Definition: shash.h:1254

TVec::Last
const TVal & Last() const
Returns a reference to the last element of the vector.
Definition: ds.h:551

TAGMUtil::LoadCmtyVV
static void LoadCmtyVV(const TStr &InFNm, TVec< TIntV > &CmtyVV)
load bipartite community affiliation graph from text file (each row contains the member node IDs for ...
Definition: agm.cpp:246

TNumericalStuff::SolveSymetricSystem
static void SolveSymetricSystem(TFltVV &A, const TFltV &b, TFltV &x)
Definition: linalg.cpp:837

TVVec::Gen
void Gen(const int &_XDim, const int &_YDim)
Definition: ds.h:2181

TGnuPlot
Definition: gnuplot.h:16

TFltPr
TPair< TFlt, TFlt > TFltPr
Definition: ds.h:99

TLogRegFit::MLEGradient
int MLEGradient(const double &ChangeEps, const int &MaxStep, const TStr PlotNm)
Definition: agm.cpp:797

TUNGraph::AddEdge
int AddEdge(const int &SrcNId, const int &DstNId)
Adds an edge between node IDs SrcNId and DstNId to the graph.
Definition: graph.cpp:92

TStrHash
Definition: hash.h:729

TAGMUtil::SaveBipartiteGephi
static void SaveBipartiteGephi(const TStr &OutFNm, const TIntV &NIDV, const TVec< TIntV > &CmtyVV, const double MaxSz, const double MinSz, const TIntStrH &NIDNameH, const THash< TInt, TIntTr > &NIDColorH, const THash< TInt, TIntTr > &CIDColorH)
save bipartite community affiliation into gexf file
Definition: agm.cpp:486

THashSet::EndI
TIter EndI() const
Definition: shash.h:1112

gpsLog10X
Definition: gnuplot.h:7

THashSet::Len
int Len() const
Definition: shash.h:1121

TPair
Definition: ds.h:32

TRnd::GetBinomialDev
double GetBinomialDev(const double &Prb, const int &Trials)
Definition: dt.cpp:154

TUNGraph::TNodeI::GetOutNId
int GetOutNId(const int &NodeN) const
Returns ID of NodeN-th out-node (the node the current node points to).
Definition: graph.h:102

TAGMFit::RunMCMC
void RunMCMC(const int &MaxIter, const int &EvalLambdaIter, const TStr &PlotFPrx=TStr())
Main procedure for fitting the AGM to a given graph using MCMC.
Definition: agmfit.cpp:366

TStr
Definition: dt.h:412

TAGMUtil::FindComsByAGM
static int FindComsByAGM(const PUNGraph &Graph, const int InitComs, const int MaxIter, const int RndSeed, const double RegGap, const double PNoCom=0.0, const TStr PltFPrx=TStr())
estimate number of communities using AGM
Definition: agm.cpp:544

TStr::Empty
bool Empty() const
Definition: dt.h:488

TStr::Fmt
static TStr Fmt(const char *FmtStr,...)
Definition: dt.cpp:1599

TVec::Pack
void Pack()
Reduces vector capacity (frees memory) to match its size.
Definition: ds.h:1005

THashSetKeyI
Definition: shash.h:1009

THash< TInt, TIntV >

TLogRegFit::GetStepSizeByLineSearch
double GetStepSizeByLineSearch(const TFltV &DeltaV, const TFltV &GradV, const double &Alpha, const double &Beta)
Definition: agm.cpp:837

TLogRegFit::Gradient
void Gradient(TFltV &GradV)
Definition: agm.cpp:869

TUNGraph::Defrag
void Defrag(const bool &OnlyNodeLinks=false)
Defragments the graph.
Definition: graph.cpp:160

TUNGraph::EndNI
TNodeI EndNI() const
Returns an iterator referring to the past-the-end node in the graph.
Definition: graph.h:211

TLogRegPredict
Definition: agm.h:194

TAGMUtil::DumpCmtyVV
static void DumpCmtyVV(const TStr &OutFNm, const TVec< TIntV > &CmtyVV)
dump bipartite community affiliation into a text file
Definition: agm.cpp:286

TPair::Val1
TVal1 Val1
Definition: ds.h:34

TUNGraph::TNodeI::GetNbrNId
int GetNbrNId(const int &NodeN) const
Returns ID of NodeN-th neighboring node.
Definition: graph.h:107

TPair::Val2
TVal2 Val2
Definition: ds.h:35

THash::Clr
void Clr(const bool &DoDel=true, const int &NoDelLim=-1, const bool &ResetDat=true)
Definition: hash.h:319

TLogRegFit::CalcLogRegGradient
PLogRegPredict CalcLogRegGradient(const TVec< TFltV > &XPt, const TFltV &yPt, const TStr &PlotNm=TStr(), const double &ChangeEps=0.01, const int &MaxStep=200, const bool InterceptPt=false)
Definition: agm.cpp:901

TLogRegFit::MLENewton
int MLENewton(const double &ChangeEps, const int &MaxStep, const TStr PlotNm)
Definition: agm.cpp:770

TUNGraph::IsNode
bool IsNode(const int &NId) const
Tests whether ID NId is a node.
Definition: graph.h:207

TSsParser::Next
bool Next()
Loads next line from the input file.
Definition: ss.cpp:412

TPt< TUNGraph >

TLinAlg::DotProduct
static double DotProduct(const TFltV &x, const TFltV &y)
Definition: linalg.cpp:165

TAGM::RndConnectInsideCommunity
static void RndConnectInsideCommunity(PUNGraph &Graph, const TIntV &CmtyV, const double &Prob, TRnd &Rnd)
Connect members of a given community by Erdos-Renyi.
Definition: agm.cpp:10

TIntTr
TTriple< TInt, TInt, TInt > TIntTr
Definition: ds.h:170

TVec::Gen
void Gen(const TSizeTy &_Vals)
Constructs a vector (an array) of _Vals elements.
Definition: ds.h:495

agm.h

TRnd::GetUniDevInt
int GetUniDevInt(const int &Range=0)
Definition: dt.cpp:39

TVec< TFlt >::GetV
static TVec< TFlt, TSizeTy > GetV(const TFlt &Val1)
Returns a vector on element Val1.
Definition: ds.h:817

TStr::CStr
char * CStr()
Definition: dt.h:476

THash::IsKey
bool IsKey(const TKey &Key) const
Definition: hash.h:216

TSsParser::IsInt
bool IsInt(const int &FldN) const
Checks whether fields FldN is an integer.
Definition: ss.h:143

TVec::Add
TSizeTy Add()
Adds a new element at the end of the vector, after its current last element.
Definition: ds.h:574

TUNGraph::BegNI
TNodeI BegNI() const
Returns an iterator referring to the first node in the graph.
Definition: graph.h:209

TVec::DelLast
void DelLast()
Removes the last element of the vector.
Definition: ds.h:635

THash::Len
int Len() const
Definition: hash.h:186

TAGM::GenAGM
static PUNGraph GenAGM(TVec< TIntV > &CmtyVV, const double &DensityCoef, const double &ScaleCoef, TRnd &Rnd=TInt::Rnd)
Definition: agm.cpp:37

THash::AddDat
TDat & AddDat(const TKey &Key)
Definition: hash.h:196

TVVec::At
const TVal & At(const int &X, const int &Y) const
Definition: ds.h:2190

TGnuPlot::PlotValV
static void PlotValV(const TVec< TVal1 > &ValV, const TStr &OutFNmPref, const TStr &Desc="", const TStr &XLabel="", const TStr &YLabel="", const TGpScaleTy &ScaleTy=gpsAuto, const bool &PowerFit=false, const TGpSeriesTy &SeriesTy=gpwLinesPoints)
Definition: gnuplot.h:398

THash::GetKey
const TKey & GetKey(const int &KeyId) const
Definition: hash.h:210

TLogRegFit
Definition: agm.h:167

TTriple::Val3
TVal3 Val3
Definition: ds.h:133

TRnd::GetPowerDev
double GetPowerDev(const double &AlphaSlope)
Definition: dt.h:47

TStrHash::GetKeyId
int GetKeyId(const char *Key) const
Definition: hash.h:922

TAGMUtil::RewireCmtyNID
static void RewireCmtyNID(THash< TInt, TIntV > &CmtyVH, TRnd &Rnd)
rewire bipartite community affiliation graphs
Definition: agm.cpp:202

Swap
void Swap(TRec &Rec1, TRec &Rec2)
Definition: bd.h:568

TFlt::Mn
static const double Mn
Definition: dt.h:1297

TVec< TInt >