1 /**************************************************************************
2 * Copyright(c) 2007-2009, ALICE Experiment at CERN, All rights reserved. *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
18 ///////////////////////////////////////////////////////////////////
20 // Implementation of the class to store the number of signal //
21 // and background events in bins of the cut values //
22 // Origin: Elena Bruna (bruna@to.infn.it) //
23 // Updated: Sergey Senyukov (senyukov@to.infn.it) //
24 // Last updated: Francesco Prino (prino@to.infn.it) //
26 ///////////////////////////////////////////////////////////////////
30 #include "AliMultiDimVector.h"
34 ClassImp(AliMultiDimVector)
35 //___________________________________________________________________________
36 AliMultiDimVector::AliMultiDimVector():TNamed("AliMultiDimVector","default"),
43 // default constructor
45 //___________________________________________________________________________
46 AliMultiDimVector::AliMultiDimVector(const char *name,const char *title, const Int_t nptbins, const Float_t* ptlimits, const Int_t npars, const Int_t *nofcells,const Float_t *loosecuts, const Float_t *tightcuts, const TString *axisTitles):TNamed(name,title),
52 // standard constructor
54 for(Int_t i=0;i<fNVariables;i++){
56 fNCutSteps[i]=nofcells[i];
57 if(loosecuts[i] <= tightcuts[i]){
58 fMinLimits[i]=loosecuts[i];
59 fMaxLimits[i]=tightcuts[i];
60 fGreaterThan[i]=kTRUE;
62 fMinLimits[i]=tightcuts[i];
63 fMaxLimits[i]=loosecuts[i];
64 fGreaterThan[i]=kFALSE;
66 fAxisTitles[i]=axisTitles[i].Data();
68 fNTotCells=ntot*fNPtBins;
69 fVett.Set(fNTotCells);
70 for(Int_t ipt=0;ipt<fNPtBins+1;ipt++) fPtLimits[ipt]=ptlimits[ipt];
71 for(Int_t ipt=fNPtBins+1;ipt<fgkMaxNPtBins+1;ipt++) fPtLimits[ipt]=999.;
72 for (ULong64_t j=0;j<fNTotCells;j++) fVett.AddAt(0,j);
74 //___________________________________________________________________________
75 AliMultiDimVector::AliMultiDimVector(const AliMultiDimVector &mv):TNamed(mv.GetName(),mv.GetTitle()),
76 fNVariables(mv.fNVariables),
77 fNPtBins(mv.fNPtBins),
79 fNTotCells(mv.fNTotCells),
80 fIsIntegrated(mv.fIsIntegrated)
83 for(Int_t i=0;i<fNVariables;i++){
84 fNCutSteps[i]=mv.GetNCutSteps(i);
85 fMinLimits[i]=mv.GetMinLimit(i);
86 fMaxLimits[i]=mv.GetMaxLimit(i);
87 fGreaterThan[i]=mv.GetGreaterThan(i);
88 fAxisTitles[i]=mv.GetAxisTitle(i);
90 fVett.Set(fNTotCells);
92 for(Int_t ipt=0;ipt<fNPtBins+1;ipt++) fPtLimits[ipt]=mv.GetPtLimit(ipt);
93 for(ULong64_t i=0;i<fNTotCells;i++) fVett[i]=mv.GetElement(i);
95 //___________________________________________________________________________
96 void AliMultiDimVector::CopyStructure(const AliMultiDimVector* mv){
97 // Sets dimensions and limit from mv
98 fNVariables=mv->GetNVariables();
99 fNPtBins=mv->GetNPtBins();
100 fNTotCells=mv->GetNTotCells();
101 fIsIntegrated=mv->IsIntegrated();
102 for(Int_t i=0;i<fNVariables;i++){
103 fNCutSteps[i]=mv->GetNCutSteps(i);
104 fMinLimits[i]=mv->GetMinLimit(i);
105 fMaxLimits[i]=mv->GetMaxLimit(i);
106 fGreaterThan[i]=mv->GetGreaterThan(i);
107 fAxisTitles[i]=mv->GetAxisTitle(i);
109 for(Int_t ipt=0;ipt<fNPtBins+1;ipt++) fPtLimits[ipt]=mv->GetPtLimit(ipt);
110 fVett.Set(fNTotCells);
112 //______________________________________________________________________
113 Bool_t AliMultiDimVector::GetIndicesFromGlobalAddress(ULong64_t globadd, Int_t *ind, Int_t &ptbin) const {
114 // returns matrix element indices and Pt bin from global index
115 if(globadd>=fNTotCells) return kFALSE;
118 Int_t nOfCellsPlusLevel[fgkMaxNVariables+1];
119 for(Int_t k=0;k<fNVariables;k++) nOfCellsPlusLevel[k]=fNCutSteps[k];
120 nOfCellsPlusLevel[fNVariables]=fNPtBins;
122 for(Int_t i=0;i<fNVariables+1;i++) prod*=nOfCellsPlusLevel[i];
123 for(Int_t i=0;i<fNVariables+1;i++){
124 prod/=nOfCellsPlusLevel[i];
125 if(i<fNVariables) ind[i]=r/prod;
131 //______________________________________________________________________
132 Bool_t AliMultiDimVector::GetCutValuesFromGlobalAddress(ULong64_t globadd, Float_t *cuts, Int_t &ptbin) const {
133 Int_t ind[fgkMaxNVariables];
134 Bool_t retcode=GetIndicesFromGlobalAddress(globadd,ind,ptbin);
135 if(!retcode) return kFALSE;
136 for(Int_t i=0;i<fNVariables;i++) cuts[i]=GetCutValue(i,ind[i]);
139 //______________________________________________________________________
140 ULong64_t AliMultiDimVector::GetGlobalAddressFromIndices(const Int_t *ind, Int_t ptbin) const {
141 // Returns the global index of the cell in the matrix
144 Int_t indexPlusLevel[fgkMaxNVariables+1];
145 Int_t nOfCellsPlusLevel[fgkMaxNVariables+1];
146 for(Int_t i=0;i<fNVariables;i++){
147 indexPlusLevel[i]=ind[i];
148 nOfCellsPlusLevel[i]=fNCutSteps[i];
150 indexPlusLevel[fNVariables]=ptbin;
151 nOfCellsPlusLevel[fNVariables]=fNPtBins;
153 for(Int_t i=0;i<fNVariables+1;i++){
154 prod=indexPlusLevel[i];
156 for(Int_t j=i+1;j<fNVariables+1;j++){
157 prod*=nOfCellsPlusLevel[j];
164 //______________________________________________________________________
165 Bool_t AliMultiDimVector::GetIndicesFromValues(const Float_t *values, Int_t *ind) const {
166 // Fills the array of matrix indices strating from variable values
167 for(Int_t i=0;i<fNVariables;i++){
169 if(values[i]<GetMinLimit(i)) return kFALSE;
170 ind[i]=(Int_t)((values[i]-fMinLimits[i])/GetCutStep(i));
171 if(ind[i]>=GetNCutSteps(i)) ind[i]=GetNCutSteps(i)-1;
173 if(values[i]>GetMaxLimit(i)) return kFALSE;
174 ind[i]=(Int_t)((fMaxLimits[i]-values[i])/GetCutStep(i));
175 if(ind[i]>=GetNCutSteps(i)) ind[i]=GetNCutSteps(i)-1;
180 //______________________________________________________________________
181 ULong64_t AliMultiDimVector::GetGlobalAddressFromValues(const Float_t *values, Int_t ptbin) const {
182 // Returns the global index of the cell in the matrix
183 Int_t ind[fgkMaxNVariables];
184 Bool_t retcode=GetIndicesFromValues(values,ind);
185 if(retcode) return GetGlobalAddressFromIndices(ind,ptbin);
187 AliError("Values out of range");
188 return fNTotCells+999;
191 //_____________________________________________________________________________
192 void AliMultiDimVector::MultiplyBy(Float_t factor){
193 // multiply the AliMultiDimVector by a constant factor
194 for(ULong64_t i=0;i<fNTotCells;i++){
196 fVett.AddAt(fVett.At(i)*factor,i);
197 else fVett.AddAt(-1,i);
201 //_____________________________________________________________________________
202 void AliMultiDimVector::Multiply(const AliMultiDimVector* mv,Float_t factor){
203 // Sets AliMultiDimVector=mv*constant factor
204 for(ULong64_t i=0;i<fNTotCells;i++){
205 if(mv->GetElement(i)>0.)
206 fVett.AddAt(mv->GetElement(i)*factor,i);
207 else fVett.AddAt(-1,i);
210 //_____________________________________________________________________________
211 void AliMultiDimVector::Multiply(const AliMultiDimVector* mv1, const AliMultiDimVector* mv2){
212 // Sets AliMultiDimVector=mv1*mv2
213 for(ULong64_t i=0;i<fNTotCells;i++){
214 if(mv1->GetElement(i)>0. && mv2->GetElement(i)>0.)
215 fVett.AddAt(mv1->GetElement(i)*mv2->GetElement(i),i);
216 else fVett.AddAt(-1,i);
219 //_____________________________________________________________________________
220 void AliMultiDimVector::Add(const AliMultiDimVector* mv){
221 // Sums contents of mv to AliMultiDimVector
222 if (mv->GetNTotCells()!=fNTotCells){
223 AliError("Different dimension of the vectors!!");
225 for(ULong64_t i=0;i<fNTotCells;i++)
226 if(mv->GetElement(i)>0. && fVett.At(i)>0.)
227 fVett.AddAt(fVett.At(i)+mv->GetElement(i),i);
228 else fVett.AddAt(-1,i);
231 //_____________________________________________________________________________
232 void AliMultiDimVector::Sum(const AliMultiDimVector* mv1, const AliMultiDimVector* mv2){
233 // Sets AliMultiDimVector=mv1+mv2
234 if (fNTotCells!=mv1->GetNTotCells()&&mv1->GetNTotCells()!=mv2->GetNTotCells()) {
235 AliError("Different dimension of the vectors!!");
238 for(ULong64_t i=0;i<mv1->GetNTotCells();i++) {
239 if(mv1->GetElement(i)>0. && mv2->GetElement(i)>0.)
240 fVett.AddAt(mv1->GetElement(i)+mv2->GetElement(i),i);
241 else fVett.AddAt(-1,i);
245 //_____________________________________________________________________________
246 void AliMultiDimVector::LinearComb(const AliMultiDimVector* mv1, Float_t norm1, const AliMultiDimVector* mv2, Float_t norm2){
247 // Sets AliMultiDimVector=n1*mv1+n2*mv2
248 if (fNTotCells!=mv1->GetNTotCells()&&mv1->GetNTotCells()!=mv2->GetNTotCells()) {
249 AliError("Different dimension of the vectors!!");
252 for(ULong64_t i=0;i<mv1->GetNTotCells();i++) {
253 if(mv1->GetElement(i)>0. && mv2->GetElement(i)>0.)
254 fVett.AddAt(norm1*mv1->GetElement(i)+norm2*mv2->GetElement(i),i);
255 else fVett.AddAt(-1,i);
259 //_____________________________________________________________________________
260 void AliMultiDimVector::DivideBy(const AliMultiDimVector* mv){
261 // Divide AliMulivector by mv
262 if (mv->GetNTotCells()!=fNTotCells) {
263 AliError("Different dimension of the vectors!!");
266 for(ULong64_t i=0;i<fNTotCells;i++)
267 if(mv->GetElement(i)!=0 &&mv->GetElement(i)>0. && fVett.At(i)>0.)
268 fVett.AddAt(fVett.At(i)/mv->GetElement(i),i);
269 else fVett.AddAt(-1,i);
273 //_____________________________________________________________________________
274 void AliMultiDimVector::Divide(const AliMultiDimVector* mv1, const AliMultiDimVector* mv2){
275 // Sets AliMultiDimVector=mv1/mv2
276 if (fNTotCells!=mv1->GetNTotCells()&&mv1->GetNTotCells()!=mv2->GetNTotCells()) {
277 AliError("Different dimension of the vectors!!");
280 for(ULong64_t i=0;i<mv1->GetNTotCells();i++)
281 if(mv2->GetElement(i)!=0&& mv2->GetElement(i)>0.&& mv1->GetElement(i)>0.)
283 fVett.AddAt(mv1->GetElement(i)/mv2->GetElement(i),i);
285 else fVett.AddAt(-1,i);
288 //_____________________________________________________________________________
289 void AliMultiDimVector::Sqrt(){
290 // Sqrt of elements of AliMultiDimVector
291 for(ULong64_t i=0;i<fNTotCells;i++) {
292 if(fVett.At(i)>=0) fVett.AddAt(TMath::Sqrt(fVett.At(i)),i);
298 //_____________________________________________________________________________
299 void AliMultiDimVector::Sqrt(const AliMultiDimVector* mv){
300 // Sets AliMultiDimVector=sqrt(mv)
301 for(ULong64_t i=0;i<fNTotCells;i++)
302 if(mv->GetElement(i)>=0) fVett.AddAt(TMath::Sqrt(mv->GetElement(i)),i);
303 else fVett.AddAt(-1,i);
305 //_____________________________________________________________________________
306 void AliMultiDimVector::FindMaximum(Float_t& maxValue, Int_t *ind , Int_t ptbin){
307 // finds the element with maximum contents
308 const ULong64_t nelem=fNTotCells/fNPtBins;
311 ULong64_t runningAddress;
312 for(ULong64_t i=0;i<nelem;i++){
313 runningAddress=ptbin+i*fNPtBins;
314 vett.AddAt(fVett[runningAddress],i);
316 maxValue=TMath::MaxElement(nelem,vett.GetArray());
317 ULong64_t maxAddress=TMath::LocMax(nelem,vett.GetArray());
318 ULong64_t maxGlobalAddress=ptbin+maxAddress*fNPtBins;
320 GetIndicesFromGlobalAddress(maxGlobalAddress,ind,checkedptbin);
323 //_____________________________________________________________________________
324 TH2F* AliMultiDimVector::Project(Int_t firstVar, Int_t secondVar, const Int_t* fixedVars, Int_t ptbin, Float_t norm){
325 // Project the AliMultiDimVector on a 2D histogram
327 TString hisName=Form("hproj%s%dv%d",GetName(),secondVar,firstVar);
328 TString hisTit=Form("%s vs. %s",fAxisTitles[secondVar].Data(),fAxisTitles[firstVar].Data());
329 TH2F* h2=new TH2F(hisName.Data(),hisTit.Data(),fNCutSteps[firstVar],fMinLimits[firstVar],fMaxLimits[firstVar],fNCutSteps[secondVar],fMinLimits[secondVar],fMaxLimits[secondVar]);
331 Int_t index[fgkMaxNVariables];
332 for(Int_t i=0;i<fNVariables;i++){
333 index[i]=fixedVars[i];
336 for(Int_t i=0;i<fNCutSteps[firstVar];i++){
337 for(Int_t j=0;j<fNCutSteps[secondVar];j++){
340 Float_t cont=GetElement(index,ptbin)/norm;
342 if(!fGreaterThan[firstVar]) bin1=fNCutSteps[firstVar]-i;
344 if(!fGreaterThan[secondVar]) bin2=fNCutSteps[secondVar]-j;
345 h2->SetBinContent(bin1,bin2,cont);
350 //_____________________________________________________________________________
351 void AliMultiDimVector::GetIntegrationLimits(Int_t iVar, Int_t iCell, Int_t& minbin, Int_t& maxbin) const {
352 // computes bin limits for integrating the AliMultiDimVector
355 if(iVar<fNVariables){
357 maxbin=fNCutSteps[iVar]-1;
360 //_____________________________________________________________________________
361 void AliMultiDimVector::GetFillRange(Int_t iVar, Int_t iCell, Int_t& minbin, Int_t& maxbin) const {
362 // computes range of cells passing the cuts for FillAndIntegrate
365 if(iVar<fNVariables){
366 minbin=0; // bin 0 corresponds to loose cuts
370 //_____________________________________________________________________________
371 void AliMultiDimVector::Integrate(){
372 // integrates the matrix
374 AliError("MultiDimVector already integrated");
377 TArrayF integral(fNTotCells);
378 for(ULong64_t i=0;i<fNTotCells;i++) integral[i]=CountsAboveCell(i);
379 for(ULong64_t i=0;i<fNTotCells;i++) fVett[i]= integral[i];
381 }//_____________________________________________________________________________
382 ULong64_t* AliMultiDimVector::GetGlobalAddressesAboveCuts(const Float_t *values, Int_t ptbin, Int_t& nVals) const{
383 // fills an array with global addresses of cells passing the cuts
385 Int_t ind[fgkMaxNVariables];
386 Bool_t retcode=GetIndicesFromValues(values,ind);
391 for(Int_t i=fNVariables; i<fgkMaxNVariables; i++) ind[i]=0;
392 Int_t mink[fgkMaxNVariables];
393 Int_t maxk[fgkMaxNVariables];
395 for(Int_t i=0;i<fgkMaxNVariables;i++){
396 GetFillRange(i,ind[i],mink[i],maxk[i]);
397 size*=(maxk[i]-mink[i]+1);
399 ULong64_t* indexes=new ULong64_t[size];
401 for(Int_t k0=mink[0]; k0<=maxk[0]; k0++){
402 for(Int_t k1=mink[1]; k1<=maxk[1]; k1++){
403 for(Int_t k2=mink[2]; k2<=maxk[2]; k2++){
404 for(Int_t k3=mink[3]; k3<=maxk[3]; k3++){
405 for(Int_t k4=mink[4]; k4<=maxk[4]; k4++){
406 for(Int_t k5=mink[5]; k5<=maxk[5]; k5++){
407 for(Int_t k6=mink[6]; k6<=maxk[6]; k6++){
408 for(Int_t k7=mink[7]; k7<=maxk[7]; k7++){
409 for(Int_t k8=mink[8]; k8<=maxk[8]; k8++){
410 for(Int_t k9=mink[9]; k9<=maxk[9]; k9++){
411 Int_t currentBin[fgkMaxNVariables]={k0,k1,k2,k3,k4,k5,k6,k7,k8,k9};
412 indexes[nVals++]=GetGlobalAddressFromIndices(currentBin,ptbin);
425 //_____________________________________________________________________________
426 Float_t AliMultiDimVector::CountsAboveCell(ULong64_t globadd) const{
427 // integrates the counts of cells above cell with address globadd
428 Int_t ind[fgkMaxNVariables];
430 GetIndicesFromGlobalAddress(globadd,ind,ptbin);
431 for(Int_t i=fNVariables; i<fgkMaxNVariables; i++) ind[i]=0;
432 Int_t mink[fgkMaxNVariables];
433 Int_t maxk[fgkMaxNVariables];
434 for(Int_t i=0;i<fgkMaxNVariables;i++){
435 GetIntegrationLimits(i,ind[i],mink[i],maxk[i]);
438 for(Int_t k0=mink[0]; k0<=maxk[0]; k0++){
439 for(Int_t k1=mink[1]; k1<=maxk[1]; k1++){
440 for(Int_t k2=mink[2]; k2<=maxk[2]; k2++){
441 for(Int_t k3=mink[3]; k3<=maxk[3]; k3++){
442 for(Int_t k4=mink[4]; k4<=maxk[4]; k4++){
443 for(Int_t k5=mink[5]; k5<=maxk[5]; k5++){
444 for(Int_t k6=mink[6]; k6<=maxk[6]; k6++){
445 for(Int_t k7=mink[7]; k7<=maxk[7]; k7++){
446 for(Int_t k8=mink[8]; k8<=maxk[8]; k8++){
447 for(Int_t k9=mink[9]; k9<=maxk[9]; k9++){
448 Int_t currentBin[fgkMaxNVariables]={k0,k1,k2,k3,k4,k5,k6,k7,k8,k9};
449 sumcont+=GetElement(currentBin,ptbin);
462 //_____________________________________________________________________________
463 void AliMultiDimVector::Fill(Float_t* values, Int_t ptbin){
464 // fills the cells of AliMultiDimVector corresponding to values
466 AliError("MultiDimVector already integrated -- Use FillAndIntegrate");
469 Int_t ind[fgkMaxNVariables];
470 Bool_t retcode=GetIndicesFromValues(values,ind);
471 for(Int_t i=fNVariables; i<fgkMaxNVariables; i++) ind[i]=0;
472 if(retcode) IncrementElement(ind,ptbin);
474 //_____________________________________________________________________________
475 void AliMultiDimVector::FillAndIntegrate(Float_t* values, Int_t ptbin){
476 // fills the cells of AliMultiDimVector passing the cuts
477 // The number of nested loops must match fgkMaxNVariables!!!!
479 Int_t ind[fgkMaxNVariables];
480 Bool_t retcode=GetIndicesFromValues(values,ind);
482 for(Int_t i=fNVariables; i<fgkMaxNVariables; i++) ind[i]=0;
483 Int_t mink[fgkMaxNVariables];
484 Int_t maxk[fgkMaxNVariables];
485 for(Int_t i=0;i<fgkMaxNVariables;i++){
486 GetFillRange(i,ind[i],mink[i],maxk[i]);
488 for(Int_t k0=mink[0]; k0<=maxk[0]; k0++){
489 for(Int_t k1=mink[1]; k1<=maxk[1]; k1++){
490 for(Int_t k2=mink[2]; k2<=maxk[2]; k2++){
491 for(Int_t k3=mink[3]; k3<=maxk[3]; k3++){
492 for(Int_t k4=mink[4]; k4<=maxk[4]; k4++){
493 for(Int_t k5=mink[5]; k5<=maxk[5]; k5++){
494 for(Int_t k6=mink[6]; k6<=maxk[6]; k6++){
495 for(Int_t k7=mink[7]; k7<=maxk[7]; k7++){
496 for(Int_t k8=mink[8]; k8<=maxk[8]; k8++){
497 for(Int_t k9=mink[9]; k9<=maxk[9]; k9++){
498 Int_t currentBin[fgkMaxNVariables]={k0,k1,k2,k3,k4,k5,k6,k7,k8,k9};
499 IncrementElement(currentBin,ptbin);
512 //_____________________________________________________________________________
513 void AliMultiDimVector::SuppressZeroBKGEffect(const AliMultiDimVector* mvBKG){
514 // Sets to zero elements for which mvBKG=0
515 for(ULong64_t i=0;i<fNTotCells;i++)
516 if(mvBKG->GetElement(i)<0.00000001) fVett.AddAt(0,i);
518 //_____________________________________________________________________________
519 AliMultiDimVector* AliMultiDimVector:: ShrinkPtBins(Int_t firstBin, Int_t lastBin){
520 // sums the elements of pt bins between firstBin and lastBin
521 if(firstBin<0 || lastBin>=fNPtBins || firstBin>=lastBin){
522 AliError("Bad numbers of Pt bins to be shrinked");
525 Int_t nofcells[fgkMaxNVariables];
526 Float_t loosecuts[fgkMaxNVariables];
527 Float_t tightcuts[fgkMaxNVariables];
528 TString axisTitles[fgkMaxNVariables];
529 for(Int_t i=0;i<fNVariables;i++){
530 nofcells[i]=fNCutSteps[i];
532 loosecuts[i]=fMinLimits[i];
533 tightcuts[i]=fMaxLimits[i];
535 loosecuts[i]=fMaxLimits[i];
536 tightcuts[i]=fMinLimits[i];
538 axisTitles[i]=fAxisTitles[i];
540 Int_t newNptbins=fNPtBins-(lastBin-firstBin);
541 Float_t ptlimits[fgkMaxNPtBins+1];
542 for(Int_t ipt=0; ipt<=firstBin;ipt++) ptlimits[ipt]=fPtLimits[ipt];
543 for(Int_t ipt=firstBin+1; ipt<newNptbins+1;ipt++) ptlimits[ipt]=fPtLimits[ipt+(lastBin-firstBin)];
544 AliMultiDimVector* shrinkedMV=new AliMultiDimVector(GetName(),GetTitle(),newNptbins,ptlimits,fNVariables,nofcells,loosecuts,tightcuts,axisTitles);
546 ULong64_t nOfPointsPerPtbin=fNTotCells/fNPtBins;
547 ULong64_t addressOld,addressNew;
549 for(npb=0;npb<firstBin;npb++){
551 for(ULong64_t k=0;k<nOfPointsPerPtbin;k++){
552 addressOld=opb+k*fNPtBins;
553 addressNew=npb+k*newNptbins;
554 shrinkedMV->SetElement(addressNew,fVett[addressOld]);
558 for(ULong64_t k=0;k<nOfPointsPerPtbin;k++){
559 Float_t summedValue=0.;
560 for(opb=firstBin;opb<=lastBin;opb++){
561 addressOld=opb+k*fNPtBins;
562 summedValue+=fVett[addressOld];
564 addressNew=npb+k*newNptbins;
565 shrinkedMV->SetElement(addressNew,summedValue);
567 for(npb=firstBin+1;npb<newNptbins;npb++){
568 opb=npb+(lastBin-firstBin);
569 for(ULong64_t k=0;k<nOfPointsPerPtbin;k++){
570 addressOld=opb+k*fNPtBins;
571 addressNew=npb+k*newNptbins;
572 shrinkedMV->SetElement(addressNew,fVett[addressOld]);
577 //_____________________________________________________________________________
578 void AliMultiDimVector::PrintStatus(){
580 printf("Number of Pt bins = %d\n",fNPtBins);
581 printf("Limits of Pt bins = ");
582 for(Int_t ib=0;ib<fNPtBins+1;ib++) printf("%6.2f ",fPtLimits[ib]);
584 printf("Number of cut variables = %d\n",fNVariables);
585 for(Int_t iv=0;iv<fNVariables;iv++){
586 printf("- Variable %d: %s\n",iv,fAxisTitles[iv].Data());
587 printf(" Nsteps= %d Rage = %6.2f %6.2f\n",
588 fNCutSteps[iv],fMinLimits[iv],fMaxLimits[iv]);