11 int CNodes = CmtyV.
Len(), CEdges;
15 CEdges = (int) (Prob * CNodes * (CNodes - 1) / 2);
18 for (
int edge = 0;
edge < CEdges; ) {
21 if (SrcNId > DstNId) {
Swap(SrcNId,DstNId); }
22 if (SrcNId != DstNId && ! NewEdgeSet.
IsKey(
TIntPr(SrcNId, DstNId))) {
33 const double ScaleCoef = (double) TargetEdges / (
double) TryG->
GetEdges();
34 return TAGM::GenAGM(CmtyVV, DensityCoef, ScaleCoef, Rnd);
40 for (
int i = 0; i < CmtyVV.
Len(); i++) {
41 Prob = ScaleCoef*pow(
double( CmtyVV[i].Len()), - DensityCoef);
42 if (Prob > 1.0) { Prob = 1; }
51 printf(
"AGM begins\n");
52 for (
int i = 0; i < CmtyVV.
Len(); i++) {
53 TIntV& CmtyV = CmtyVV[i];
54 for (
int u = 0; u < CmtyV.
Len(); u++) {
55 if ( G->
IsNode(CmtyV[u])) {
continue; }
58 double Prob = CProbV[i];
63 for (
int c = 0; c < CmtyVV.
Len(); c++) {
64 for (
int u = 0; u < CmtyVV[c].
Len(); u++) {
83 while (SzSeq.
Len() < SeqLen) {
85 if (Sz >= Min && Sz <= Max) {
92 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){
94 for (
int i = 0; i < Nodes; i++) {
97 GenCmtyVVFromPL(CmtyVV, NIDV, Nodes, Coms, ComSzAlpha, MemAlpha, MinSz, MaxSz, MinK, MaxK, Rnd);
101 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){
102 if (Coms == 0 || Nodes == 0) {
108 GenCmtyVVFromPL(CmtyVV, NIDV, Nodes, Coms, ComSzAlpha, MemAlpha, MinSz, MaxSz, MinK, MaxK, Rnd);
112 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){
113 if (Coms == 0 || Nodes == 0) {
117 TIntV ComSzSeq, MemSeq;
121 for (
int i = 0; i < ComSzSeq.
Len(); i++) {
124 for (
int i = 0; i < MemSeq.
Len(); i++) {
125 NIDMemPrV.
Add(
TIntPr(NIDV[i], MemSeq[i]));
132 const int Nodes = NIDMemPrV.
Len(), Coms = CIDSzPrV.
Len();
137 for (
int i = 0;i < CIDSzPrV.
Len(); i++) {
138 for (
int j = 0; j < CIDSzPrV[i].Val2; j++) {
139 CDegV.
Add(CIDSzPrV[i].Val1);
142 for (
int i = 0; i < NIDMemPrV.
Len(); i++) {
143 for (
int j = 0; j < NIDMemPrV[i].Val2; j++) {
144 NDegV.
Add(NIDMemPrV[i].Val1);
147 while (CDegV.
Len() < (int) (1.2 * Nodes)) {
150 while (NDegV.
Len() < CDegV.
Len()) {
153 printf(
"Total Mem: %d, Total Sz: %d\n",NDegV.
Len(), CDegV.
Len());
155 while (c++ < 15 && CDegV.
Len() > 1) {
156 for (
int i = 0; i < CDegV.
Len(); i++) {
159 if (CNIDSet.
IsKey(
TIntPr(CDegV[u], NDegV[v]))) {
continue; }
161 HitNodes.
AddKey(NDegV[v]);
162 if (u == CDegV.
Len() - 1) { CDegV.
DelLast(); }
164 CDegV[u] = CDegV.
Last();
167 if (v == NDegV.
Len() - 1) { NDegV.
DelLast(); }
169 NDegV[v] = NDegV.
Last();
175 for (
int i = 0; i < Nodes; i++) {
176 int NID = NIDMemPrV[i].Val1;
177 if (! HitNodes.
IsKey(NID)) {
183 for (
int i = 0; i < CNIDSet.
Len(); i++) {
184 TIntPr CNIDPr = CNIDSet[i];
194 for (
int i = 0; i < CmtyVVIn.
Len(); i++) {
195 CmtyVH.
AddDat(i, CmtyVVIn[i]);
206 for (
int i = 0; i < CmtyVH.
Len(); i++) {
207 int CID = CmtyVH.
GetKey(i);
208 for (
int j = 0; j < CmtyVH[i].
Len(); j++) {
209 int NID = CmtyVH[i][j];
216 while (c++ < 15 && CDegV.
Len() > 1){
217 for (
int i = 0; i < CDegV.
Len(); i++) {
220 if (CNIDSet.IsKey(
TIntPr(CDegV[u], NDegV[v]))) {
continue; }
221 CNIDSet.AddKey(
TIntPr(CDegV[u], NDegV[v]));
222 if (u == CDegV.
Len() - 1) {
225 CDegV[u] = CDegV.
Last();
228 if ( v == NDegV.
Len() - 1) {
231 NDegV[v] = NDegV.Last();
236 for (
int i = 0; i < CNIDSet.Len(); i++) {
237 TIntPr CNIDPr = CNIDSet[i];
239 NewCmtyVH.AddDat(CNIDPr.
Val1);
240 NewCmtyVH.GetDat(CNIDPr.
Val1).Add(CNIDPr.
Val2);
252 for (
int i = 0; i < Ss.
GetFlds(); i++) {
261 printf(
"community loading completed (%d communities)\n",CmtyVV.
Len());
272 for (
int i = BeginCol; i < Ss.
GetFlds(); i++) {
277 if (CmtyV.
Len() < MinSz) {
continue; }
282 printf(
"community loading completed (%d communities)\n",CmtyVV.
Len());
287 FILE* F = fopen(OutFNm.
CStr(),
"wt");
288 for (
int i = 0; i < CmtyVV.
Len(); i++) {
289 for (
int j = 0; j < CmtyVV[i].
Len(); j++) {
290 fprintf(F,
"%d\t", (
int) CmtyVV[i][j]);
299 FILE* F = fopen(OutFNm.
CStr(),
"wt");
300 for (
int c = 0; c < CmtyVV.
Len(); c++) {
301 for (
int u = 0; u < CmtyVV[c].
Len(); u++) {
302 if (NIDNmH.
IsKey(CmtyVV[c][u])){
303 fprintf(F,
"%s\t", NIDNmH.
GetDat(CmtyVV[c][u]).
CStr());
306 fprintf(F,
"%d\t", (
int) CmtyVV[c][u]);
317 for (
int i = 0; i < CmtyVV.
Len(); i++) {
318 M += CmtyVV[i].
Len();
327 for (
int j = 0;j < HI.GetDat().Len(); j++) {
328 int NID = HI.GetDat()[j];
337 for (
int i = 0; i < CmtyVV.
Len(); i++){
339 for (
int j = 0; j < CmtyVV[i].
Len(); j++) {
340 int NID = CmtyVV[i][j];
349 for (
int u = 0; u < NIDV.
Len(); u++) {
352 for (
int i = 0; i < CmtyVV.
Len(); i++){
354 for (
int j = 0; j < CmtyVV[i].
Len(); j++) {
355 int NID = CmtyVV[i][j];
363 for (
int i = 0; i < CmtyVV.
Len(); i++){
366 int NID = SI.GetKey();
373 int CID = HI.GetKey();
374 for (
int j = 0; j < HI.GetDat().Len(); j++) {
375 int NID = HI.GetDat()[j];
382 for (
int i = 0; i < CmtyVH.
Len(); i++){
383 int CID = CmtyVH.
GetKey(i);
384 for (
int j = 0; j < CmtyVH[i].
Len(); j++) {
385 int NID = CmtyVH[i][j];
393 for (
int i = 0; i < CmtyVV.
Len(); i++) {
394 CmtyVH.
AddDat(i, CmtyVV[i]);
419 if (B.
IsKey(it.GetKey())) n++;
422 if (A.
IsKey(it.GetKey())) n++;
432 FILE* F = fopen(OutFNm.
CStr(),
"wt");
433 fprintf(F,
"<?xml version='1.0' encoding='UTF-8'?>\n");
434 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");
435 fprintf(F,
"\t<graph mode='static' defaultedgetype='undirected'>\n");
436 if (CmtyVVAtr.
Len() > 0) {
437 fprintf(F,
"\t<attributes class='node'>\n");
438 for (
int c = 0; c < CmtyVVAtr.
Len(); c++) {
439 fprintf(F,
"\t\t<attribute id='%d' title='c%d' type='boolean'>", c, c);
440 fprintf(F,
"\t\t<default>false</default>\n");
441 fprintf(F,
"\t\t</attribute>\n");
443 fprintf(F,
"\t</attributes>\n");
445 fprintf(F,
"\t\t<nodes>\n");
447 int NID = NI.GetId();
452 double SizeStep = (MaxSz - MinSz) / (
double) CmtyVVAtr.
Len();
453 if (NIDComVHAtr.
IsKey(NID)) {
454 Size = MinSz + SizeStep * (double) NIDComVHAtr.
GetDat(NID).
Len();
457 fprintf(F,
"\t\t\t<node id='%d' label='%s'>\n", NID, Label.
CStr());
458 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);
459 fprintf(F,
"\t\t\t\t<viz:size value='%.3f'/>\n", Size);
461 if (NIDComVHAtr.
IsKey(NID)) {
462 fprintf(F,
"\t\t\t\t<attvalues>\n");
463 for (
int c = 0; c < NIDComVHAtr.
GetDat(NID).
Len(); c++) {
464 int CID = NIDComVHAtr.
GetDat(NID)[c];
465 fprintf(F,
"\t\t\t\t\t<attvalue for='%d' value='true'/>\n", CID);
467 fprintf(F,
"\t\t\t\t</attvalues>\n");
470 fprintf(F,
"\t\t\t</node>\n");
472 fprintf(F,
"\t\t</nodes>\n");
475 fprintf(F,
"\t\t<edges>\n");
477 fprintf(F,
"\t\t\t<edge id='%d' source='%d' target='%d'/>\n", EID++, EI.GetSrcNId(), EI.GetDstNId());
479 fprintf(F,
"\t\t</edges>\n");
480 fprintf(F,
"\t</graph>\n");
481 fprintf(F,
"</gexf>\n");
488 if (CmtyVV.
Len() == 0) {
return; }
489 double NXMin = 0.1, YMin = 0.1, NXMax = 250.00, YMax = 30.0;
490 double CXMin = 0.3 * NXMax, CXMax = 0.7 * NXMax;
491 double CStep = (CXMax - CXMin) / (
double) CmtyVV.
Len(), NStep = (NXMax - NXMin) / (
double) NIDV.
Len();
495 FILE* F = fopen(OutFNm.
CStr(),
"wt");
496 fprintf(F,
"<?xml version='1.0' encoding='UTF-8'?>\n");
497 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");
498 fprintf(F,
"\t<graph mode='static' defaultedgetype='directed'>\n");
499 fprintf(F,
"\t\t<nodes>\n");
500 for (
int c = 0; c < CmtyVV.
Len(); c++) {
502 double XPos = c * CStep + CXMin;
504 fprintf(F,
"\t\t\t<node id='C%d' label='C%d'>\n", CID, CID);
505 fprintf(F,
"\t\t\t\t<viz:color r='%d' g='%d' b='%d'/>\n", Color.
Val1.Val, Color.
Val2.Val, Color.
Val3.Val);
506 fprintf(F,
"\t\t\t\t<viz:size value='%.3f'/>\n", MaxSz);
507 fprintf(F,
"\t\t\t\t<viz:shape value='square'/>\n");
508 fprintf(F,
"\t\t\t\t<viz:position x='%f' y='%f' z='0.0'/>\n", XPos, YMax);
509 fprintf(F,
"\t\t\t</node>\n");
512 for (
int u = 0;u < NIDV.
Len(); u++) {
516 double XPos = NXMin + u * NStep;
519 fprintf(F,
"\t\t\t<node id='%d' label='%s'>\n", NID, Label.
CStr());
520 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);
521 fprintf(F,
"\t\t\t\t<viz:size value='%.3f'/>\n", Size);
522 fprintf(F,
"\t\t\t\t<viz:shape value='square'/>\n");
523 fprintf(F,
"\t\t\t\t<viz:position x='%f' y='%f' z='0.0'/>\n", XPos, YMin);
524 fprintf(F,
"\t\t\t</node>\n");
526 fprintf(F,
"\t\t</nodes>\n");
527 fprintf(F,
"\t\t<edges>\n");
529 for (
int u = 0;u < NIDV.
Len(); u++) {
531 if (NIDComVH.
IsKey(NID)) {
532 for (
int c = 0; c < NIDComVH.
GetDat(NID).
Len(); c++) {
533 int CID = NIDComVH.
GetDat(NID)[c];
534 fprintf(F,
"\t\t\t<edge id='%d' source='C%d' target='%d'/>\n", EID++, CID, NID);
538 fprintf(F,
"\t\t</edges>\n");
539 fprintf(F,
"\t</graph>\n");
540 fprintf(F,
"</gexf>\n");
546 int LambdaIter = 100;
547 if (Graph->
GetNodes() < 200) { LambdaIter = 1; }
548 if (Graph->
GetNodes() < 200 && Graph->
GetEdges() > 2000) { LambdaIter = 100; }
551 TAGMFit AGMFitM(Graph, InitComs, RndSeed);
552 if (PNoCom > 0.0) { AGMFitM.
SetPNoCom(PNoCom); }
553 AGMFitM.
RunMCMC(MaxIter, LambdaIter,
"");
558 for (
int r = 0; r < 25; r++) {
559 RegV.
Add(RegV.
Last() * RegGap);
561 TFltPrV RegComsV, RegLV, RegBICV;
564 for (
int r = 0; r < RegV.
Len(); r++) {
565 double RegCoef = RegV[r];
572 int NumLowQ = EstCmtyVV.
Len();
573 RegComsV.
Add(
TFltPr(RegCoef, (
double) NumLowQ));
575 if (EstCmtyVV.
Len() > 0) {
576 TAGMFit AFTemp(Graph, EstCmtyVV, Rnd);
580 BICV.
Add(-2.0 * CurL + (
double) EstCmtyVV.
Len() * log((
double) Graph->
GetNodes() * (Graph->
GetNodes() - 1) / 2.0));
587 if (LV.
Len() == 0) {
return 2; }
588 else if (LV[0] == LV.
Last()) {
return (
int) TMath::Mx<TFlt>(2.0, RegComsV[LV.
Len() - 1].Val2); }
597 for (
int l = 0; l < ValueV.
Len(); l++) {
598 if (ValueV[l] < MinValue) { MinValue = ValueV[l]; }
599 if (ValueV[l] > MaxValue) { MaxValue = ValueV[l]; }
601 while (ValueV.
Len() < RegV.
Len()) { ValueV.
Add(MinValue); }
602 double RangeVal = MaxValue - MinValue;
603 for (
int l = 0; l < ValueV.
Len(); l++) {
604 RegValueV.
Add(
TFltPr(RegV[l],
double(MaxL) * (ValueV[l] - MinValue) / RangeVal));
609 TFltV& ValueV = BICV;
612 for (
int l = 0; l < ValueV.
Len(); l++) {
613 if (ValueV[l] < MinValue) { MinValue = ValueV[l]; }
614 if (ValueV[l] > MaxValue) { MaxValue = ValueV[l]; }
616 while (ValueV.
Len() < RegV.
Len()) { ValueV.
Add(MaxValue); }
617 double RangeVal = MaxValue - MinValue;
618 for (
int l = 0; l < ValueV.
Len(); l++) {
619 RegValueV.
Add(
TFltPr(RegV[l],
double(MaxL) * (ValueV[l] - MinValue) / RangeVal));
626 for (
int l = 0; l < RegLV.
Len(); l++) {
628 YV[l] = RegLV[l].Val2 / (double) MaxL;
633 for (
int l = 0; l < RegLV.
Len(); l++) {
634 LRV.
Add(
TFltPr(RegV[l], LRMd->GetCfy(XV[l])));
639 int NumComs = 0, IdxRegDrop = 0;
640 double LRThres = 1.1, RegDrop;
641 double LeftReg = 0.0, RightReg = 0.0;
643 LRMd->GetTheta(Theta);
644 RegDrop = (- Theta[1] - LRThres) / Theta[0];
645 if (RegDrop <= XV[0][0]) { NumComs = (int) RegComsV[0].Val2; }
646 else if (RegDrop >= XV.Last()[0]) { NumComs = (int) RegComsV.
Last().
Val2; }
648 for (
int i = 0; i < XV.Len(); i++) {
649 if (XV[i][0] > RegDrop) { IdxRegDrop = i;
break; }
652 if (IdxRegDrop == 0) {
653 printf(
"Error!! RegDrop:%f, Theta[0]:%f, Theta[1]:%f\n", RegDrop, Theta[0].Val, Theta[1].Val);
654 for (
int l = 0; l < RegLV.
Len(); l++) {
655 printf(
"X[%d]:%f, Y[%d]:%f\n", l, XV[l][0].Val, l, YV[l].Val);
659 LeftReg = RegDrop - XV[IdxRegDrop - 1][0];
660 RightReg = XV[IdxRegDrop][0] - RegDrop;
661 NumComs = (int)
TMath::Round( (RightReg * RegComsV[IdxRegDrop - 1].Val2 + LeftReg * RegComsV[IdxRegDrop].Val2) / (LeftReg + RightReg));
665 printf(
"Num Coms:%d\n", NumComs);
666 if (NumComs < 2) { NumComs = 2; }
668 if (PltFPrx.
Len() > 0) {
676 GPC.SetTitle(PlotTitle);
677 GPC.SavePng(PltFPrx +
".l.png");
684 const int Edges2 = Edges >= 0 ? 2*Edges : Graph->
GetEdges();
685 int Vol = 0, Cut = 0;
687 for (
int i = 0; i < CmtyS.
Len(); i++) {
688 if (! Graph->
IsNode(CmtyS[i])) {
continue; }
690 for (
int e = 0; e < NI.
GetOutDeg(); e++) {
697 if (2 * Vol > Edges2) { Phi = Cut / double (Edges2 - Vol); }
698 else if (Vol == 0) { Phi = 0.0; }
699 else { Phi = Cut / double(Vol); }
701 if (Vol == Edges2) { Phi = 1.0; }
710 for (
int e = 0; e < NI.
GetDeg(); e++) {
719 bool HSingular =
false;
720 for (
int i = 0; i < HVV.
GetXDim(); i++) {
721 if (HVV(i,i) == 0.0) {
725 DeltaLV[i] = GradV[i] / HVV(i, i);
729 for (
int r = 0; r <
Theta.
Len(); r++) {
730 for (
int c = 0; c <
Theta.
Len(); c++) {
731 HVV(r, c) = - HVV(r, c);
738 for (
int i = 0; i < DeltaLV.
Len(); i++) {
739 DeltaLV[i] = - DeltaLV[i];
750 for (
int i = 0; i <
X.
Len(); i++) {
751 for (
int r = 0; r <
Theta.
Len(); r++) {
752 HVV.
At(r, r) += - (
X[i][r] * OutV[i] * (1 - OutV[i]) *
X[i][r]);
753 for (
int c = r + 1; c <
Theta.
Len(); c++) {
754 HVV.
At(r, c) += - (
X[i][r] * OutV[i] * (1 - OutV[i]) *
X[i][c]);
755 HVV.
At(c, r) += - (
X[i][r] * OutV[i] * (1 - OutV[i]) *
X[i][c]);
775 double MinVal = -1e10, MaxVal = 1e10;
776 for(iter = 0; iter < MaxStep; iter++) {
781 if (Increment <= ChangeEps) {
break;}
783 for(
int i = 0; i <
Theta.
Len(); i++) {
784 double Change = LearnRate * DeltaLV[i];
790 if (! PlotNm.
Empty()) {
791 printf(
"MLE with Newton method completed with %d iterations(%s)\n",iter,ExeTm.
GetTmStr());
802 double MinVal = -1e10, MaxVal = 1e10;
803 double GradCutOff = 100000;
804 for(iter = 0; iter < MaxStep; iter++) {
806 for(
int i = 0; i <
Theta.
Len(); i++) {
807 if (GradV[i] < -GradCutOff) { GradV[i] = -GradCutOff; }
808 if (GradV[i] > GradCutOff) { GradV[i] = GradCutOff; }
809 if (
Theta[i] <= MinVal && GradV[i] < 0) { GradV[i] = 0.0; }
810 if (
Theta[i] >= MaxVal && GradV[i] > 0) { GradV[i] = 0.0; }
812 double Alpha = 0.15, Beta = 0.9;
816 for(
int i = 0; i <
Theta.
Len(); i++) {
817 double Change = LearnRate * GradV[i];
822 if (! PlotNm.
Empty()) {
829 if (! PlotNm.
Empty()) {
832 printf(
"MLE for Lambda completed with %d iterations(%s)\n",iter,ExeTm.
GetTmStr());
838 double StepSize = 1.0;
842 double MinVal = -1e10, MaxVal = 1e10;
843 for(
int iter = 0; ; iter++) {
844 for (
int i = 0; i <
Theta.
Len(); i++){
845 NewThetaV[i] =
Theta[i] + StepSize * DeltaV[i];
846 if (NewThetaV[i] < MinVal) { NewThetaV[i] = MinVal; }
847 if (NewThetaV[i] > MaxVal) { NewThetaV[i] = MaxVal; }
862 for (
int r = 0; r < OutV.
Len(); r++) {
863 L +=
Y[r] * log(OutV[r]);
864 L += (1 -
Y[r]) * log(1 - OutV[r]);
873 for (
int r = 0; r <
X.
Len(); r++) {
875 for (
int m = 0; m <
M; m++) {
876 GradV[m] += (
Y[r] - OutV[r]) *
X[r][m];
887 if (Intercept ==
false) {
888 for (
int r = 0; r <
X.
Len(); r++) {
X[r].
Add(1); }
891 for (
int r = 0; r <
X.
Len(); r++) {
IAssert(
X[r].Len() ==
M); }
892 for (
int r = 0; r <
Y.
Len(); r++) {
893 if (
Y[r] >= 0.99999) {
Y[r] = 0.99999; }
894 if (
Y[r] <= 0.00001) {
Y[r] = 0.00001; }
905 if (Intercept ==
false) {
906 for (
int r = 0; r <
X.
Len(); r++) {
X[r].
Add(1); }
909 for (
int r = 0; r <
X.
Len(); r++) {
IAssert(
X[r].Len() ==
M); }
910 for (
int r = 0; r <
Y.
Len(); r++) {
911 if (
Y[r] >= 0.99999) {
Y[r] = 0.99999; }
912 if (
Y[r] <= 0.00001) {
Y[r] = 0.00001; }
923 int len = AttrV.
Len();
925 if (len < NewTheta.
Len()) { res = NewTheta.
Last(); }
926 for (
int i = 0; i < len; i++) {
927 if (i < NewTheta.
Len()) { res += AttrV[i] * NewTheta[i]; }
929 double mu = 1 / (1 + exp(-res));
935 for (
int r = 0; r < X.
Len(); r++) {
936 OutV[r] =
GetCfy(X[r], NewTheta);
Edge iterator. Only forward iteration (operator++) is supported.
TPair< TInt, TInt > TIntPr
static void GetNbhCom(const PUNGraph &Graph, const int NID, TIntSet &NBCmtyS)
TIter EndI() const
Returns an iterator referring to the past-the-end element in the vector.
void GetNewtonStep(TFltVV &HVV, const TFltV &GradV, TFltV &DeltaLV)
static double Norm(const TFltV &x)
static int TotalMemberships(const TVec< TIntV > &CmtyVV)
total number of memberships (== sum of the sizes of communities)
void GetDatV(TVec< TDat > &DatV) const
TEdgeI EndEI() const
Returns an iterator referring to the past-the-end edge in the graph.
static void RewireCmtyVV(const TVec< TIntV > &CmtyVVIn, TVec< TIntV > &CmtyVVOut, TRnd &Rnd)
rewire bipartite community affiliation graphs
static void GetNodeMembership(THash< TInt, TIntSet > &NIDComVH, const TVec< TIntV > &CmtyVV)
get hash table of
static void GetCfy(const TVec< TFltV > &X, TFltV &OutV, const TFltV &NewTheta)
void SetPNoCom(const double &Epsilon)
Set Epsilon (the probability that two nodes sharing no communities connect) to the default value...
void GetNIdV(TIntV &NIdV) const
Gets a vector IDs of all nodes in the graph.
int AddNode(int NId=-1)
Adds a node of ID NId to the graph.
double Likelihood()
COMMENT.
static void GenPLSeq(TIntV &SzSeq, const int &SeqLen, const double &Alpha, TRnd &Rnd, const int &Min, const int &Max)
AGMUtil:: Utilities for AGM.
int GetEdges() const
Returns the number of edges in the graph.
TSizeTy Len() const
Returns the number of elements in the vector.
Node iterator. Only forward iteration (operator++) is supported.
static int Intersection(const TIntV &C1, const TIntV &C2)
void GetKeyV(TVec< TKey > &KeyV) const
void Gen(const int &ExpectVals)
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...
const TDat & GetDat(const TKey &Key) const
static void GetIntersection(const THashSet< TInt > &A, const THashSet< TInt > &B, THashSet< TInt > &C)
Fitting the Affilialiton Graph Model (AGM).
static double GetConductance(const PUNGraph &Graph, const TIntSet &CmtyS, const int Edges)
int GetFlds() const
Returns the number of fields in the current line.
bool IsKey(const TKey &Key) const
int GetNodes() const
Returns the number of nodes in the graph.
const char * GetFld(const int &FldN) const
Returns the contents of the field at index FldN.
TSsFmt
Spread-Sheet Separator Format.
TPair< TInt, TFlt > TIntFltPr
int GetDeg() const
Returns degree of the current node.
const char * GetTmStr() const
static void SaveGephi(const TStr &OutFNm, const PUNGraph &G, const TVec< TIntV > &CmtyVVAtr, const double MaxSz, const double MinSz)
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...
int GetOutDeg() const
Returns out-degree of the current node (returns same as value GetDeg() since the graph is undirected)...
void Clr(const bool &DoDel=true, const TSizeTy &NoDelLim=-1)
Clears the contents of the vector.
void GetCmtyVV(TVec< TIntV > &CmtyVV, const double QMax=2.0)
Get communities whose p_c is higher than 1 - QMax.
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.
bool IsKey(const char *Key) const
void Hessian(TFltVV &HVV)
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)
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...
static double Round(const double &Val)
Whitespace (space or tab) separated.
TNodeI GetNI(const int &NId) const
Returns an iterator referring to the node of ID NId in the graph.
void SetRegCoef(const double Val)
TEdgeI BegEI() const
Returns an iterator referring to the first edge in the graph.
static PUNGraph New()
Static constructor that returns a pointer to the graph. Call: PUNGraph Graph = TUNGraph::New().
int AddKey(const TKey &Key)
const TVal & Last() const
Returns a reference to the last element of the vector.
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 ...
static void SolveSymetricSystem(TFltVV &A, const TFltV &b, TFltV &x)
TPair< TFlt, TFlt > TFltPr
int MLEGradient(const double &ChangeEps, const int &MaxStep, const TStr PlotNm)
int AddEdge(const int &SrcNId, const int &DstNId)
Adds an edge between node IDs SrcNId and DstNId to the graph.
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
double GetBinomialDev(const double &Prb, const int &Trials)
int GetOutNId(const int &NodeN) const
Returns ID of NodeN-th out-node (the node the current node points to).
void RunMCMC(const int &MaxIter, const int &EvalLambdaIter, const TStr &PlotFPrx=TStr())
Main procedure for fitting the AGM to a given graph using MCMC.
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
static TStr Fmt(const char *FmtStr,...)
void Pack()
Reduces vector capacity (frees memory) to match its size.
double GetStepSizeByLineSearch(const TFltV &DeltaV, const TFltV &GradV, const double &Alpha, const double &Beta)
void Gradient(TFltV &GradV)
void Defrag(const bool &OnlyNodeLinks=false)
Defragments the graph.
TNodeI EndNI() const
Returns an iterator referring to the past-the-end node in the graph.
static void DumpCmtyVV(const TStr &OutFNm, const TVec< TIntV > &CmtyVV)
dump bipartite community affiliation into a text file
int GetNbrNId(const int &NodeN) const
Returns ID of NodeN-th neighboring node.
void Clr(const bool &DoDel=true, const int &NoDelLim=-1, const bool &ResetDat=true)
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)
int MLENewton(const double &ChangeEps, const int &MaxStep, const TStr PlotNm)
bool IsNode(const int &NId) const
Tests whether ID NId is a node.
bool Next()
Loads next line from the input file.
static double DotProduct(const TFltV &x, const TFltV &y)
static void RndConnectInsideCommunity(PUNGraph &Graph, const TIntV &CmtyV, const double &Prob, TRnd &Rnd)
Connect members of a given community by Erdos-Renyi.
TTriple< TInt, TInt, TInt > TIntTr
void Gen(const TSizeTy &_Vals)
Constructs a vector (an array) of _Vals elements.
int GetUniDevInt(const int &Range=0)
static TVec< TFlt, int > GetV(const TFlt &Val1)
Returns a vector on element Val1.
bool IsKey(const TKey &Key) const
bool IsInt(const int &FldN) const
Checks whether fields FldN is an integer.
TSizeTy Add()
Adds a new element at the end of the vector, after its current last element.
TNodeI BegNI() const
Returns an iterator referring to the first node in the graph.
void DelLast()
Removes the last element of the vector.
static PUNGraph GenAGM(TVec< TIntV > &CmtyVV, const double &DensityCoef, const double &ScaleCoef, TRnd &Rnd=TInt::Rnd)
TDat & AddDat(const TKey &Key)
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)
void Gen(const TSizeTy &_XDim, const TSizeTy &_YDim)
const TKey & GetKey(const int &KeyId) const
double GetPowerDev(const double &AlphaSlope)
int GetKeyId(const char *Key) const
static void RewireCmtyNID(THash< TInt, TIntV > &CmtyVH, TRnd &Rnd)
rewire bipartite community affiliation graphs
void Swap(TRec &Rec1, TRec &Rec2)
const TVal & At(const TSizeTy &X, const TSizeTy &Y) const