TKDTree class now in ROOT
authorabercuci <abercuci@f7af4fe6-9843-0410-8265-dc069ae4e863>
Thu, 11 Dec 2008 19:42:13 +0000 (19:42 +0000)
committerabercuci <abercuci@f7af4fe6-9843-0410-8265-dc069ae4e863>
Thu, 11 Dec 2008 19:42:13 +0000 (19:42 +0000)
STAT/CMake_libSTAT.txt
STAT/STATLinkDef.h
STAT/TKDInterpolatorBase.cxx
STAT/TKDInterpolatorBase.h
STAT/TKDPDF.cxx
STAT/TKDPDF.h

index 91e7bc2..fa7eaad 100644 (file)
@@ -1,7 +1,6 @@
 # -*- mode: cmake -*-
 
 set(SRCS
-  TKDTree.cxx 
   TKDInterpolatorBase.cxx 
   TKDNodeInfo.cxx 
   TKDPDF.cxx 
index 3fa5253..5b09bac 100644 (file)
@@ -7,12 +7,6 @@
 #pragma link off all classes;
 #pragma link off all functions;
 
-#pragma link C++ class TKDTree<Int_t, Float_t>+;
-#pragma link C++ class TKDTree<Int_t, Double_t>+;
-#pragma link C++ typedef TKDTreeID;
-#pragma link C++ typedef TKDTreeIF;
-
-
 #pragma link C++ class TKDInterpolatorBase+;
 #pragma link C++ class TKDNodeInfo+;
 #pragma link C++ class TKDPDF+;
index 1999b95..3ae3870 100644 (file)
@@ -31,17 +31,17 @@ ClassImp(TKDInterpolatorBase)
 
 //_________________________________________________________________
 TKDInterpolatorBase::TKDInterpolatorBase(Int_t dim) :
-       fNSize(dim)
-       ,fNTNodes(0)
-       ,fTNodes(0x0)
-       ,fStatus(4)
-       ,fLambda(1 + dim + (dim*(dim+1)>>1))
-       ,fDepth(-1)
-       ,fAlpha(.5)
-       ,fRefPoints(0x0)
-       ,fBuffer(0x0)
-       ,fKDhelper(0x0)
-       ,fFitter(0x0)
+  fNSize(dim)
+  ,fNTNodes(0)
+  ,fTNodes(0x0)
+  ,fStatus(4)
+  ,fLambda(1 + dim + (dim*(dim+1)>>1))
+  ,fDepth(-1)
+  ,fAlpha(.5)
+  ,fRefPoints(0x0)
+  ,fBuffer(0x0)
+  ,fKDhelper(0x0)
+  ,fFitter(0x0)
 {
 // Default constructor. To be used with care since in this case building
 // of data structure is completly left to the user responsability.
@@ -50,46 +50,46 @@ TKDInterpolatorBase::TKDInterpolatorBase(Int_t dim) :
 //_________________________________________________________________
 void   TKDInterpolatorBase::Build(Int_t n)
 {
-       // allocate memory for data
+  // allocate memory for data
 
-       if(fTNodes) delete fTNodes;
-       fNTNodes = n;
-       fTNodes = new TClonesArray("TKDNodeInfo", fNTNodes);
-       for(int in=0; in<fNTNodes; in++) new ((*fTNodes)[in]) TKDNodeInfo(fNSize);
+  if(fTNodes) delete fTNodes;
+  fNTNodes = n;
+  fTNodes = new TClonesArray("TKDNodeInfo", fNTNodes);
+  for(int in=0; in<fNTNodes; in++) new ((*fTNodes)[in]) TKDNodeInfo(fNSize);
 }
 
 //_________________________________________________________________
 TKDInterpolatorBase::~TKDInterpolatorBase()
 {
-       if(fFitter) delete fFitter;
-       if(fKDhelper) delete fKDhelper;
-       if(fBuffer) delete [] fBuffer;
-       
-       if(fRefPoints){
-               for(int idim=0; idim<fNSize; idim++) delete [] fRefPoints[idim] ;
-               delete [] fRefPoints;
-       }
-       if(fTNodes) delete fTNodes;
+  if(fFitter) delete fFitter;
+  if(fKDhelper) delete fKDhelper;
+  if(fBuffer) delete [] fBuffer;
+  
+  if(fRefPoints){
+    for(int idim=0; idim<fNSize; idim++) delete [] fRefPoints[idim] ;
+    delete [] fRefPoints;
+  }
+  if(fTNodes) delete fTNodes;
 }
 
 
 //__________________________________________________________________
 Bool_t TKDInterpolatorBase::GetCOGPoint(Int_t inode, Float_t *&coord, Float_t &val, Float_t &err) const
 {
-       if(inode < 0 || inode > fNTNodes) return kFALSE;
+  if(inode < 0 || inode > fNTNodes) return kFALSE;
 
-       TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[inode];
-       coord = &(node->Data()[0]);
-       val = node->Val()[0];
-       err = node->Val()[1];
-       return kTRUE;
+  TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[inode];
+  coord = &(node->Data()[0]);
+  val = node->Val()[0];
+  err = node->Val()[1];
+  return kTRUE;
 }
 
 //_________________________________________________________________
 TKDNodeInfo* TKDInterpolatorBase::GetNodeInfo(Int_t inode) const
 {
-       if(!fTNodes || inode >= fNTNodes) return 0x0;
-       return (TKDNodeInfo*)(*fTNodes)[inode];
+  if(!fTNodes || inode >= fNTNodes) return 0x0;
+  return (TKDNodeInfo*)(*fTNodes)[inode];
 }
 
 
@@ -98,17 +98,17 @@ void TKDInterpolatorBase::GetStatus()
 {
 // Prints the status of the interpolator
 
-       printf("Interpolator Status :\n");
-       printf("  Dim    : %d [%d]\n", fNSize, fLambda);
-       printf("  Method : %s\n", fStatus&1 ? "INT" : "COG");
-       printf("  Store  : %s\n", fStatus&2 ? "YES" : "NO");
-       printf("  Weights: %s\n", fStatus&4 ? "YES" : "NO");
-       
-       printf("fNTNodes %d\n", fNTNodes);        //Number of evaluation data points
-       for(int i=0; i<fNTNodes; i++){
-               TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[i]; 
-               printf("%d ", i); node->Print();
-       }
+  printf("Interpolator Status :\n");
+  printf("  Dim    : %d [%d]\n", fNSize, fLambda);
+  printf("  Method : %s\n", fStatus&1 ? "INT" : "COG");
+  printf("  Store  : %s\n", fStatus&2 ? "YES" : "NO");
+  printf("  Weights: %s\n", fStatus&4 ? "YES" : "NO");
+  
+  printf("fNTNodes %d\n", fNTNodes);        //Number of evaluation data points
+  for(int i=0; i<fNTNodes; i++){
+    TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[i]; 
+    printf("%d ", i); node->Print();
+  }
 }
 
 //_________________________________________________________________
@@ -120,119 +120,116 @@ Double_t TKDInterpolatorBase::Eval(const Double_t *point, Double_t &result, Doub
 //
 // 1. The default method used for interpolation is kCOG.
 // 2. The initial number of neighbors used for the estimation is set to Int(alpha*fLambda) (alpha = 1.5)
-                       
-       Float_t pointF[50]; // local Float_t conversion for "point"
-       for(int idim=0; idim<fNSize; idim++) pointF[idim] = (Float_t)point[idim];
-       Int_t nodeIndex = GetNodeIndex(pointF);
-       if(nodeIndex<0){
-               result = 0.;
-               error = 1.E10;
-               return 0.;
-       }
-       TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[nodeIndex];
-       if((fStatus&1) && node->Cov() && !force) return node->CookPDF(point, result, error);
-
-       // Allocate memory
-       if(!fBuffer) fBuffer = new Double_t[2*fLambda];
-       if(!fKDhelper){ 
-               fRefPoints = new Float_t*[fNSize];
-               for(int id=0; id<fNSize; id++){
-                       fRefPoints[id] = new Float_t[fNTNodes];
-                       for(int in=0; in<fNTNodes; in++) fRefPoints[id][in] = ((TKDNodeInfo*)(*fTNodes)[in])->Data()[id];
-               }
-               fKDhelper = new TKDTreeIF(fNTNodes, fNSize, 30, fRefPoints);
-               fKDhelper->MakeBoundaries();
-       }
-       if(!fFitter) fFitter = new TLinearFitter(fLambda, Form("hyp%d", fLambda-1));
-       
-       // generate parabolic for nD
-       //Float_t alpha = Float_t(2*lambda + 1) / fNTNodes; // the bandwidth or smoothing parameter
-       //Int_t npoints = Int_t(alpha * fNTNodes);
-       //printf("Params : %d NPoints %d\n", lambda, npoints);
-       // prepare workers
-
-       Int_t *index,  // indexes of NN 
-             ipar,    // local looping variable
-                               npoints = Int_t((1.+fAlpha)*fLambda); // number of data points used for interpolation
-       Float_t *dist, // distances of NN
-                                       d,     // NN normalized distance
-                                       w0,    // work
-                                       w;     // tri-cubic weight function
-
-       do{
-               // find nearest neighbors
-               for(int idim=0; idim<fNSize; idim++) pointF[idim] = (Float_t)point[idim];
-               if(!fKDhelper->FindNearestNeighbors(pointF, npoints+1, index, dist)){
-                       Error("Eval()", Form("Failed retriving %d neighbours for point:", npoints));
-                       for(int idim=0; idim<fNSize; idim++) printf("%f ", point[idim]);
-                       printf("\n");
-                       return -1;
-               }
-               // add points to fitter
-               fFitter->ClearPoints();
-               TKDNodeInfo *tnode = 0x0;
-               for(int in=0; in<npoints; in++){
-                       tnode = (TKDNodeInfo*)(*fTNodes)[index[in]];
-                       //tnode->Print();
-                       if(fStatus&1){ // INT
-                               Float_t *bounds = &(tnode->Data()[fNSize]);
-                               ipar = 0;
-                               for(int idim=0; idim<fNSize; idim++){
-                                       fBuffer[ipar++] = .5*(bounds[2*idim] + bounds[2*idim+1]);
-                                       fBuffer[ipar++] = (bounds[2*idim]*bounds[2*idim] + bounds[2*idim] * bounds[2*idim+1] + bounds[2*idim+1] * bounds[2*idim+1])/3.;
-                                       for(int jdim=idim+1; jdim<fNSize; jdim++) fBuffer[ipar++] = (bounds[2*idim] + bounds[2*idim+1]) * (bounds[2*jdim] + bounds[2*jdim+1]) * .25;
-                               }
-                       } else { // COG
-                               Float_t *p = &(tnode->Data()[0]);
-                               ipar = 0;
-                               for(int idim=0; idim<fNSize; idim++){
-                                       fBuffer[ipar++] = p[idim];
-                                       for(int jdim=idim; jdim<fNSize; jdim++) fBuffer[ipar++] = p[idim]*p[jdim];
-                               }
-                       }
-
-                       // calculate tri-cubic weighting function
-                       if(fStatus&4){
-                               d = dist[in]/ dist[npoints];
-                               w0 = (1. - d*d*d); w = w0*w0*w0;
-                       } else w = 1.;
-                        
+      
+  Float_t pointF[50]; // local Float_t conversion for "point"
+  for(int idim=0; idim<fNSize; idim++) pointF[idim] = (Float_t)point[idim];
+  Int_t nodeIndex = GetNodeIndex(pointF);
+  if(nodeIndex<0){
+    result = 0.;
+    error = 1.E10;
+    return 0.;
+  }
+  TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[nodeIndex];
+  if((fStatus&1) && node->Cov() && !force) return node->CookPDF(point, result, error);
+
+  // Allocate memory
+  if(!fBuffer) fBuffer = new Double_t[2*fLambda];
+  if(!fKDhelper){ 
+    fRefPoints = new Float_t*[fNSize];
+    for(int id=0; id<fNSize; id++){
+      fRefPoints[id] = new Float_t[fNTNodes];
+      for(int in=0; in<fNTNodes; in++) fRefPoints[id][in] = ((TKDNodeInfo*)(*fTNodes)[in])->Data()[id];
+    }
+    fKDhelper = new TKDTreeIF(fNTNodes, fNSize, 30, fRefPoints);
+    fKDhelper->MakeBoundaries();
+  }
+  if(!fFitter) fFitter = new TLinearFitter(fLambda, Form("hyp%d", fLambda-1));
+  
+  // generate parabolic for nD
+  //Float_t alpha = Float_t(2*lambda + 1) / fNTNodes; // the bandwidth or smoothing parameter
+  //Int_t npoints = Int_t(alpha * fNTNodes);
+  //printf("Params : %d NPoints %d\n", lambda, npoints);
+  // prepare workers
+
+  Int_t ipar,    // local looping variable
+        npoints = Int_t((1.+fAlpha)*fLambda); // number of data points used for interpolation
+  Int_t *index = new Int_t[2*npoints];  // indexes of NN 
+  Float_t *dist = new Float_t[2*npoints], // distances of NN
+          d,     // NN normalized distance
+          w0,    // work
+          w;     // tri-cubic weight function
+
+  do{
+    // find nearest neighbors
+    for(int idim=0; idim<fNSize; idim++) pointF[idim] = (Float_t)point[idim];
+    fKDhelper->FindNearestNeighbors(pointF, npoints+1, index, dist);
+    // add points to fitter
+    fFitter->ClearPoints();
+    TKDNodeInfo *tnode = 0x0;
+    for(int in=0; in<npoints; in++){
+      tnode = (TKDNodeInfo*)(*fTNodes)[index[in]];
+      //tnode->Print();
+      if(fStatus&1){ // INT
+        Float_t *bounds = &(tnode->Data()[fNSize]);
+        ipar = 0;
+        for(int idim=0; idim<fNSize; idim++){
+          fBuffer[ipar++] = .5*(bounds[2*idim] + bounds[2*idim+1]);
+          fBuffer[ipar++] = (bounds[2*idim]*bounds[2*idim] + bounds[2*idim] * bounds[2*idim+1] + bounds[2*idim+1] * bounds[2*idim+1])/3.;
+          for(int jdim=idim+1; jdim<fNSize; jdim++) fBuffer[ipar++] = (bounds[2*idim] + bounds[2*idim+1]) * (bounds[2*jdim] + bounds[2*jdim+1]) * .25;
+        }
+      } else { // COG
+        Float_t *p = &(tnode->Data()[0]);
+        ipar = 0;
+        for(int idim=0; idim<fNSize; idim++){
+          fBuffer[ipar++] = p[idim];
+          for(int jdim=idim; jdim<fNSize; jdim++) fBuffer[ipar++] = p[idim]*p[jdim];
+        }
+      }
+
+      // calculate tri-cubic weighting function
+      if(fStatus&4){
+        d = dist[in]/ dist[npoints];
+        w0 = (1. - d*d*d); w = w0*w0*w0;
+      } else w = 1.;
+      
 //                     printf("x[");
 //                     for(int idim=0; idim<fLambda-1; idim++) printf("%f ", fBuffer[idim]);
 //                     printf("]  v[%f +- %f] (%f, %f)\n", tnode->Val()[0], tnode->Val()[1]/w, tnode->Val()[1], w);
-                       fFitter->AddPoint(fBuffer, tnode->Val()[0], tnode->Val()[1]/w);
-               }
-               npoints += 4;
-       } while(fFitter->Eval());
-
-       // retrive fitter results
-       TMatrixD cov(fLambda, fLambda);
-       TVectorD par(fLambda);
-       fFitter->GetCovarianceMatrix(cov);
-       fFitter->GetParameters(par);
-       Double_t chi2 = fFitter->GetChisquare()/(npoints - 4 - fLambda);
-
-       // store results
-       if(fStatus&2 && fStatus&1) node->Store(par, cov);
-               
-       // Build df/dpi|x values
-       Double_t *fdfdp = &fBuffer[fLambda];
-       ipar = 0;
-       fdfdp[ipar++] = 1.;
-       for(int idim=0; idim<fNSize; idim++){
-               fdfdp[ipar++] = point[idim];
-               for(int jdim=idim; jdim<fNSize; jdim++) fdfdp[ipar++] = point[idim]*point[jdim];
-       }
-
-       // calculate estimation
-       result =0.; error = 0.;
-       for(int i=0; i<fLambda; i++){
-               result += fdfdp[i]*par(i);
-               for(int j=0; j<fLambda; j++) error += fdfdp[i]*fdfdp[j]*cov(i,j);
-       }       
-       error = TMath::Sqrt(error);
-
-       return chi2;
+      fFitter->AddPoint(fBuffer, tnode->Val()[0], tnode->Val()[1]/w);
+    }
+    npoints += 4;
+  } while(fFitter->Eval());
+  delete [] index;
+  delete [] dist;
+
+  // retrive fitter results
+  TMatrixD cov(fLambda, fLambda);
+  TVectorD par(fLambda);
+  fFitter->GetCovarianceMatrix(cov);
+  fFitter->GetParameters(par);
+  Double_t chi2 = fFitter->GetChisquare()/(npoints - 4 - fLambda);
+
+  // store results
+  if(fStatus&2 && fStatus&1) node->Store(par, cov);
+    
+  // Build df/dpi|x values
+  Double_t *fdfdp = &fBuffer[fLambda];
+  ipar = 0;
+  fdfdp[ipar++] = 1.;
+  for(int idim=0; idim<fNSize; idim++){
+    fdfdp[ipar++] = point[idim];
+    for(int jdim=idim; jdim<fNSize; jdim++) fdfdp[ipar++] = point[idim]*point[jdim];
+  }
+
+  // calculate estimation
+  result =0.; error = 0.;
+  for(int i=0; i<fLambda; i++){
+    result += fdfdp[i]*par(i);
+    for(int j=0; j<fLambda; j++) error += fdfdp[i]*fdfdp[j]*cov(i,j);
+  }    
+  error = TMath::Sqrt(error);
+
+  return chi2;
 }
 
 //_________________________________________________________________
@@ -247,44 +244,44 @@ void TKDInterpolatorBase::DrawBins(UInt_t ax1, UInt_t ax2, Float_t ax1min, Float
 // but don't delete it. Abusing this function may cause memory leaks !
 
 
-       
-       TH2 *h2 = new TH2S("hNodes", "", 100, ax1min, ax1max, 100, ax2min, ax2max);
-       h2->GetXaxis()->SetTitle(Form("x_{%d}", ax1));
-       h2->GetYaxis()->SetTitle(Form("x_{%d}", ax2));
-       h2->Draw();
-       
-       const Float_t kBorder = 0.;//1.E-4;
-       TBox *boxArray = new TBox[fNTNodes], *box;
-       Float_t *bounds = 0x0;
-       for(int inode = 0; inode < fNTNodes; inode++){
-               box = &boxArray[inode];
-               box->SetFillStyle(3002);
-               box->SetFillColor(50+inode/*Int_t(gRandom->Uniform()*50.)*/);
-               
-               bounds = &(((TKDNodeInfo*)(*fTNodes)[inode])->Data()[fNSize]);
-               box->DrawBox(bounds[2*ax1]+kBorder, bounds[2*ax2]+kBorder, bounds[2*ax1+1]-kBorder, bounds[2*ax2+1]-kBorder);
-       }
-
-       // Draw reference points
-       TGraph *ref = new TGraph(fNTNodes);
-       ref->SetMarkerStyle(3);
-       ref->SetMarkerSize(.7);
-       ref->SetMarkerColor(2);
-       for(int inode = 0; inode < fNTNodes; inode++){
-               TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[inode];
-               ref->SetPoint(inode, node->Data()[ax1], node->Data()[ax2]);
-       }
-       ref->Draw("p");
-       return;
+  
+  TH2 *h2 = new TH2S("hNodes", "", 100, ax1min, ax1max, 100, ax2min, ax2max);
+  h2->GetXaxis()->SetTitle(Form("x_{%d}", ax1));
+  h2->GetYaxis()->SetTitle(Form("x_{%d}", ax2));
+  h2->Draw();
+  
+  const Float_t kBorder = 0.;//1.E-4;
+  TBox *boxArray = new TBox[fNTNodes], *box;
+  Float_t *bounds = 0x0;
+  for(int inode = 0; inode < fNTNodes; inode++){
+    box = &boxArray[inode];
+    box->SetFillStyle(3002);
+    box->SetFillColor(50+inode/*Int_t(gRandom->Uniform()*50.)*/);
+    
+    bounds = &(((TKDNodeInfo*)(*fTNodes)[inode])->Data()[fNSize]);
+    box->DrawBox(bounds[2*ax1]+kBorder, bounds[2*ax2]+kBorder, bounds[2*ax1+1]-kBorder, bounds[2*ax2+1]-kBorder);
+  }
+
+  // Draw reference points
+  TGraph *ref = new TGraph(fNTNodes);
+  ref->SetMarkerStyle(3);
+  ref->SetMarkerSize(.7);
+  ref->SetMarkerColor(2);
+  for(int inode = 0; inode < fNTNodes; inode++){
+    TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[inode];
+    ref->SetPoint(inode, node->Data()[ax1], node->Data()[ax2]);
+  }
+  ref->Draw("p");
+  return;
 }
 
 //__________________________________________________________________
 void TKDInterpolatorBase::SetInterpolationMethod(Bool_t on)
 {
 // Set interpolation bit to "on".
-       
-       if(on) fStatus += fStatus&1 ? 0 : 1;
-       else fStatus += fStatus&1 ? -1 : 0;
+  
+  if(on) fStatus += fStatus&1 ? 0 : 1;
+  else fStatus += fStatus&1 ? -1 : 0;
 }
 
 
@@ -292,16 +289,16 @@ void TKDInterpolatorBase::SetInterpolationMethod(Bool_t on)
 void TKDInterpolatorBase::SetStore(Bool_t on)
 {
 // Set store bit to "on"
-       
-       if(on) fStatus += fStatus&2 ? 0 : 2;
-       else fStatus += fStatus&2 ? -2 : 0;
+  
+  if(on) fStatus += fStatus&2 ? 0 : 2;
+  else fStatus += fStatus&2 ? -2 : 0;
 }
 
 //_________________________________________________________________
 void TKDInterpolatorBase::SetWeights(Bool_t on)
 {
 // Set weights bit to "on"
-       
-       if(on) fStatus += fStatus&4 ? 0 : 4;
-       else fStatus += fStatus&4 ? -4 : 0;
+  
+  if(on) fStatus += fStatus&4 ? 0 : 4;
+  else fStatus += fStatus&4 ? -4 : 0;
 }
index ae7097b..2674cf2 100644 (file)
@@ -26,49 +26,49 @@ class TKDNodeInfo;
 class TKDInterpolatorBase
 {
 public:        
-       TKDInterpolatorBase(Int_t size = 0);
-       virtual ~TKDInterpolatorBase();
+  TKDInterpolatorBase(Int_t size = 0);
+  virtual ~TKDInterpolatorBase();
 
-       Double_t   Eval(const Double_t *point, Double_t &result, Double_t &error, Bool_t force = kFALSE);
-       virtual Int_t GetNodeIndex(const Float_t *p) = 0;
-       Float_t    GetAlpha() const {return fAlpha;}
-       Bool_t     GetCOGPoint(Int_t node, Float_t *&coord, Float_t &val, Float_t &error) const;
-       Bool_t     GetInterpolationMethod() const {return fStatus&1;}
-       TKDNodeInfo* GetNodeInfo(Int_t inode) const;
-       Int_t      GetNTNodes() const {return fNTNodes;}
-       void       GetStatus();
-       Bool_t     GetStore() const {return fStatus&2;}
-       Bool_t     GetWeights() const {return fStatus&4;}
+  Double_t   Eval(const Double_t *point, Double_t &result, Double_t &error, Bool_t force = kFALSE);
+  virtual Int_t GetNodeIndex(const Float_t *p) = 0;
+  Float_t    GetAlpha() const {return fAlpha;}
+  Bool_t     GetCOGPoint(Int_t node, Float_t *&coord, Float_t &val, Float_t &error) const;
+  Bool_t     GetInterpolationMethod() const {return fStatus&1;}
+  TKDNodeInfo* GetNodeInfo(Int_t inode) const;
+  Int_t      GetNTNodes() const {return fNTNodes;}
+  void       GetStatus();
+  Bool_t     GetStore() const {return fStatus&2;}
+  Bool_t     GetWeights() const {return fStatus&4;}
 
-       void       DrawBins(UInt_t ax1 = 0, UInt_t ax2 = 1, Float_t ax1min=-1., Float_t ax1max=1., Float_t ax2min=-1., Float_t ax2max=1.);
-       void       SetAlpha(Float_t a){if(a>0.) fAlpha = a;}
-       void       SetInterpolationMethod(Bool_t on = kTRUE);
-       void       SetStore(Bool_t on = kTRUE);
-       void       SetWeights(Bool_t on = kTRUE);
+  void       DrawBins(UInt_t ax1 = 0, UInt_t ax2 = 1, Float_t ax1min=-1., Float_t ax1max=1., Float_t ax2min=-1., Float_t ax2max=1.);
+  void       SetAlpha(Float_t a){if(a>0.) fAlpha = a;}
+  void       SetInterpolationMethod(Bool_t on = kTRUE);
+  void       SetStore(Bool_t on = kTRUE);
+  void       SetWeights(Bool_t on = kTRUE);
 
 protected:
-       virtual void      Build(Int_t nnodes);
+  virtual void      Build(Int_t nnodes);
 
 private:
-       TKDInterpolatorBase(const TKDInterpolatorBase &);
-       TKDInterpolatorBase& operator=(const TKDInterpolatorBase &);
+  TKDInterpolatorBase(const TKDInterpolatorBase &);
+  TKDInterpolatorBase& operator=(const TKDInterpolatorBase &);
 
 protected:
-       Int_t         fNSize;       // data dimension
-       Int_t         fNTNodes;     //Number of evaluation data points
-       TClonesArray  *fTNodes;     //interpolation nodes
+  Int_t         fNSize;       // data dimension
+  Int_t         fNTNodes;     //Number of evaluation data points
+  TClonesArray  *fTNodes;     //interpolation nodes
 
 //private:
-       UChar_t       fStatus;      // status of the interpolator
-       UChar_t       fLambda;      // number of parameters in polynom
-       Short_t             fDepth;       //! depth of the KD Tree structure used
-       Float_t       fAlpha;       // alpha parameter
-       Float_t       **fRefPoints; //! temporary storage of COG data
-       Double_t            *fBuffer;     //! working space [2*fLambda]
-       TKDTree<Int_t, Float_t> *fKDhelper;      //! kNN finder
-       TLinearFitter *fFitter;     //! linear fitter   
+  UChar_t       fStatus;      // status of the interpolator
+  UChar_t       fLambda;      // number of parameters in polynom
+  Short_t                  fDepth;       //! depth of the KD Tree structure used
+  Float_t       fAlpha;       // alpha parameter
+  Float_t       **fRefPoints; //! temporary storage of COG data
+  Double_t         *fBuffer;     //! working space [2*fLambda]
+  TKDTree<Int_t, Float_t> *fKDhelper;      //! kNN finder
+  TLinearFitter *fFitter;     //! linear fitter        
 
-       ClassDef(TKDInterpolatorBase, 1)   // data interpolator based on KD tree
+  ClassDef(TKDInterpolatorBase, 1)   // data interpolator based on KD tree
 };
 
 
index c8fa07e..72bf23a 100644 (file)
@@ -16,8 +16,8 @@ ClassImp(TKDPDF)
 
 //_________________________________________________________________
 TKDPDF::TKDPDF() :
-       TKDTreeIF()
-       ,TKDInterpolatorBase()
+  TKDTreeIF()
+  ,TKDInterpolatorBase()
 {
 // Default constructor. To be used with care since in this case building
 // of data structure is completly left to the user responsability.
@@ -25,19 +25,19 @@ TKDPDF::TKDPDF() :
 
 //_________________________________________________________________
 TKDPDF::TKDPDF(Int_t npoints, Int_t ndim, UInt_t bsize, Float_t **data) :
-       TKDTreeIF(npoints, ndim, bsize, data)
-       ,TKDInterpolatorBase(ndim)
+  TKDTreeIF(npoints, ndim, bsize, data)
+  ,TKDInterpolatorBase(ndim)
 {
 // Wrapper constructor for the TKDTree.
 
-       Build();
+  Build();
 }
 
 
 //_________________________________________________________________
 TKDPDF::TKDPDF(TTree *t, const Char_t *var, const Char_t *cut, UInt_t bsize, Long64_t nentries, Long64_t firstentry) :
-       TKDTreeIF()
-       ,TKDInterpolatorBase()
+  TKDTreeIF()
+  ,TKDInterpolatorBase()
 {
 // Alocate data from a tree. The variables which have to be analysed are
 // defined in the "var" parameter as a colon separated list. The format should
@@ -45,34 +45,34 @@ TKDPDF::TKDPDF(TTree *t, const Char_t *var, const Char_t *cut, UInt_t bsize, Lon
 //
 // 
 
-       TObjArray *vars = TString(var).Tokenize(":");
-       fNDim = vars->GetEntriesFast(); fNDimm = 2*fNDim;
-       fNSize = fNDim;
-       if(fNDim > 6/*kDimMax*/) Warning("TKDPDF(TTree*, const Char_t, const Char_t, UInt_t)", Form("Variable number exceed maximum dimension %d. Results are unpredictable.", 6/*kDimMax*/));
-       fBucketSize = bsize;
-
-       Int_t np;
-       Double_t *v;
-       for(int idim=0; idim<fNDim; idim++){
-               if(!(np = t->Draw(((TObjString*)(*vars)[idim])->GetName(), cut, "goff", nentries, firstentry))){
-                       Warning("TKDPDF(TTree*, const Char_t, const Char_t, UInt_t)", Form("Can not access data for keys %s. Key defined on tree :", ((TObjString*)(*vars)[idim])->GetName() ));
-                       TIterator *it = (t->GetListOfLeaves())->MakeIterator();
-                       TObject *o;
-                       while((o = (*it)())) printf("\t%s\n", o->GetName());
-                       continue;
-               }
-               if(!fNpoints){
-                       fNpoints = np;
-                       //Info("TKDPDF(TTree*, const Char_t, const Char_t, UInt_t)", Form("Allocating %d data points in %d dimensions.", fNpoints, fNDim));
-                       fData = new Float_t*[fNDim];
-                       for(int idim=0; idim<fNDim; idim++) fData[idim] = new Float_t[fNpoints];
-                       fDataOwner = kTRUE;
-               }
-               v = t->GetV1();
-               for(int ip=0; ip<fNpoints; ip++) fData[idim][ip] = (Float_t)v[ip];
-       }
-       TKDTreeIF::Build();
-       Build();
+  TObjArray *vars = TString(var).Tokenize(":");
+  fNDim = vars->GetEntriesFast(); fNDimm = 2*fNDim;
+  fNSize = fNDim;
+  if(fNDim > 6/*kDimMax*/) Warning("TKDPDF(TTree*, const Char_t, const Char_t, UInt_t)", Form("Variable number exceed maximum dimension %d. Results are unpredictable.", 6/*kDimMax*/));
+  fBucketSize = bsize;
+
+  Int_t np;
+  Double_t *v;
+  for(int idim=0; idim<fNDim; idim++){
+    if(!(np = t->Draw(((TObjString*)(*vars)[idim])->GetName(), cut, "goff", nentries, firstentry))){
+      Warning("TKDPDF(TTree*, const Char_t, const Char_t, UInt_t)", Form("Can not access data for keys %s. Key defined on tree :", ((TObjString*)(*vars)[idim])->GetName() ));
+      TIterator *it = (t->GetListOfLeaves())->MakeIterator();
+      TObject *o;
+      while((o = (*it)())) printf("\t%s\n", o->GetName());
+      continue;
+    }
+    if(!fNPoints){
+      fNPoints = np;
+      //Info("TKDPDF(TTree*, const Char_t, const Char_t, UInt_t)", Form("Allocating %d data points in %d dimensions.", fNpoints, fNDim));
+      fData = new Float_t*[fNDim];
+      for(int idim=0; idim<fNDim; idim++) fData[idim] = new Float_t[fNPoints];
+      fDataOwner = kTRUE;
+    }
+    v = t->GetV1();
+    for(int ip=0; ip<fNPoints; ip++) fData[idim][ip] = (Float_t)v[ip];
+  }
+  TKDTreeIF::Build();
+  Build();
 }
 
 //_________________________________________________________________
@@ -87,55 +87,55 @@ void TKDPDF::Build(Int_t)
 //  - estimation points 
 //  - corresponding PDF values
 
-       fNTNodes = fNpoints/fBucketSize + ((fNpoints%fBucketSize)?1:0);/*TKDTreeIF::GetNTNodes();*/
-       if(!fBoundaries) MakeBoundaries();
-       fLambda = 1 + fNDim + (fNDim*(fNDim+1)>>1);
-       //printf("after MakeBoundaries() %d\n", memory());
-       
-       // allocate interpolation nodes
-       TKDInterpolatorBase::Build(fNTNodes);
-
-       TKDNodeInfo *node = 0x0;
-       Float_t *bounds = 0x0;
-       Int_t *indexPoints;
-       for(int inode=0, tnode = fNnodes; inode<fNTNodes-1; inode++, tnode++){
-               node = (TKDNodeInfo*)(*fTNodes)[inode];
-               node->Val()[0] =  Float_t(fBucketSize)/fNpoints;
-               bounds = GetBoundary(tnode);
-               for(int idim=0; idim<fNDim; idim++) node->Val()[0] /= (bounds[2*idim+1] - bounds[2*idim]);
-               node->Val()[1] =  node->Val()[0]/TMath::Sqrt(float(fBucketSize));
-               
-               indexPoints = GetPointsIndexes(tnode);
-               // loop points in this terminal node
-               for(int idim=0; idim<fNDim; idim++){
-                       node->Data()[idim] = 0.;
-                       for(int ip = 0; ip<fBucketSize; ip++) node->Data()[idim] += fData[idim][indexPoints[ip]];
-                       node->Data()[idim] /= fBucketSize;
-               }
-               memcpy(&(node->Data()[fNDim]), bounds, fNDimm*sizeof(Float_t));
-       }
-
-       // analyze last (incomplete) terminal node
-       Int_t counts = fNpoints%fBucketSize;
-       counts = counts ? counts : fBucketSize;
-       Int_t inode = fNTNodes - 1, tnode = inode + fNnodes;
-       node = (TKDNodeInfo*)(*fTNodes)[inode];
-       node->Val()[0] =  Float_t(counts)/fNpoints;
-       bounds = GetBoundary(tnode);
-       for(int idim=0; idim<fNDim; idim++) node->Val()[0] /= (bounds[2*idim+1] - bounds[2*idim]);
-       node->Val()[1] =  node->Val()[0]/TMath::Sqrt(float(counts));
-
-       // loop points in this terminal node
-       indexPoints = GetPointsIndexes(tnode);
-       for(int idim=0; idim<fNDim; idim++){
-               node->Data()[idim] = 0.;
-               for(int ip = 0; ip<counts; ip++) node->Data()[idim] += fData[idim][indexPoints[ip]];
-               node->Data()[idim] /= counts;
-       }
-       memcpy(&(node->Data()[fNDim]), bounds, fNDimm*sizeof(Float_t));
-
-       delete [] fBoundaries;
-       fBoundaries = 0x0;
+  fNTNodes = fNPoints/fBucketSize + ((fNPoints%fBucketSize)?1:0);/*TKDTreeIF::GetNTNodes();*/
+  if(!fBoundaries) MakeBoundaries();
+  fLambda = 1 + fNDim + (fNDim*(fNDim+1)>>1);
+  //printf("after MakeBoundaries() %d\n", memory());
+  
+  // allocate interpolation nodes
+  TKDInterpolatorBase::Build(fNTNodes);
+
+  TKDNodeInfo *node = 0x0;
+  Float_t *bounds = 0x0;
+  Int_t *indexPoints;
+  for(int inode=0, tnode = fNNodes; inode<fNTNodes-1; inode++, tnode++){
+    node = (TKDNodeInfo*)(*fTNodes)[inode];
+    node->Val()[0] =  Float_t(fBucketSize)/fNPoints;
+    bounds = GetBoundary(tnode);
+    for(int idim=0; idim<fNDim; idim++) node->Val()[0] /= (bounds[2*idim+1] - bounds[2*idim]);
+    node->Val()[1] =  node->Val()[0]/TMath::Sqrt(float(fBucketSize));
+    
+    indexPoints = GetPointsIndexes(tnode);
+    // loop points in this terminal node
+    for(int idim=0; idim<fNDim; idim++){
+      node->Data()[idim] = 0.;
+      for(int ip = 0; ip<fBucketSize; ip++) node->Data()[idim] += fData[idim][indexPoints[ip]];
+      node->Data()[idim] /= fBucketSize;
+    }
+    memcpy(&(node->Data()[fNDim]), bounds, fNDimm*sizeof(Float_t));
+  }
+
+  // analyze last (incomplete) terminal node
+  Int_t counts = fNPoints%fBucketSize;
+  counts = counts ? counts : fBucketSize;
+  Int_t inode = fNTNodes - 1, tnode = inode + fNNodes;
+  node = (TKDNodeInfo*)(*fTNodes)[inode];
+  node->Val()[0] =  Float_t(counts)/fNPoints;
+  bounds = GetBoundary(tnode);
+  for(int idim=0; idim<fNDim; idim++) node->Val()[0] /= (bounds[2*idim+1] - bounds[2*idim]);
+  node->Val()[1] =  node->Val()[0]/TMath::Sqrt(float(counts));
+
+  // loop points in this terminal node
+  indexPoints = GetPointsIndexes(tnode);
+  for(int idim=0; idim<fNDim; idim++){
+    node->Data()[idim] = 0.;
+    for(int ip = 0; ip<counts; ip++) node->Data()[idim] += fData[idim][indexPoints[ip]];
+    node->Data()[idim] /= counts;
+  }
+  memcpy(&(node->Data()[fNDim]), bounds, fNDimm*sizeof(Float_t));
+
+  delete [] fBoundaries;
+  fBoundaries = 0x0;
 }
 
 
@@ -148,37 +148,37 @@ void TKDPDF::DrawNode(Int_t tnode, UInt_t ax1, UInt_t ax2)
 // This function creates some graphical objects
 // but don't delete it. Abusing this function may cause memory leaks !
 
-       if(tnode < 0 || tnode >= fNTNodes){
-               Warning("DrawNode()", Form("Terminal node %d outside defined range.", tnode));
-               return;
-       }
-
-       Int_t inode = tnode;
-       tnode += fNnodes;
-       // select zone of interest in the indexes array
-       Int_t *index = GetPointsIndexes(tnode);
-       Int_t nPoints = (tnode == 2*fNnodes) ? fNpoints%fBucketSize : fBucketSize;
-
-       // draw data points
-       TGraph *g = new TGraph(nPoints);
-       g->SetMarkerStyle(7);
-       for(int ip = 0; ip<nPoints; ip++) g->SetPoint(ip, fData[ax1][index[ip]], fData[ax2][index[ip]]);
-
-       // draw estimation point
-       TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[inode];
-       TMarker *m=new TMarker(node->Data()[ax1], node->Data()[ax2], 20);
-       m->SetMarkerColor(2);
-       m->SetMarkerSize(1.7);
-       
-       // draw node contour
-       Float_t *bounds = GetBoundary(tnode);
-       TBox *n = new TBox(bounds[2*ax1], bounds[2*ax2], bounds[2*ax1+1], bounds[2*ax2+1]);
-       n->SetFillStyle(0);
-
-       g->Draw("ap");
-       m->Draw();
-       n->Draw();
-       
-       return;
+  if(tnode < 0 || tnode >= fNTNodes){
+    Warning("DrawNode()", Form("Terminal node %d outside defined range.", tnode));
+    return;
+  }
+
+  Int_t inode = tnode;
+  tnode += fNNodes;
+  // select zone of interest in the indexes array
+  Int_t *index = GetPointsIndexes(tnode);
+  Int_t nPoints = (tnode == 2*fNNodes) ? fNPoints%fBucketSize : fBucketSize;
+
+  // draw data points
+  TGraph *g = new TGraph(nPoints);
+  g->SetMarkerStyle(7);
+  for(int ip = 0; ip<nPoints; ip++) g->SetPoint(ip, fData[ax1][index[ip]], fData[ax2][index[ip]]);
+
+  // draw estimation point
+  TKDNodeInfo *node = (TKDNodeInfo*)(*fTNodes)[inode];
+  TMarker *m=new TMarker(node->Data()[ax1], node->Data()[ax2], 20);
+  m->SetMarkerColor(2);
+  m->SetMarkerSize(1.7);
+  
+  // draw node contour
+  Float_t *bounds = GetBoundary(tnode);
+  TBox *n = new TBox(bounds[2*ax1], bounds[2*ax2], bounds[2*ax1+1], bounds[2*ax2+1]);
+  n->SetFillStyle(0);
+
+  g->Draw("ap");
+  m->Draw();
+  n->Draw();
+  
+  return;
 }
 
index 846e3e0..8ec6a38 100644 (file)
@@ -1,14 +1,14 @@
 #ifndef ROOT_TKDPDF
 #define ROOT_TKDPDF
 
-#ifndef ROOT_TKDTree
-#include "TKDTree.h"
-#endif
-
 #ifndef ROOT_TKDInterpolatorBase
 #include "TKDInterpolatorBase.h"
 #endif
 
+#ifndef ROOT_TKDTree
+#include "TKDTree.h"
+#endif
+
 // Non parametric interpolation class based on local polinomial regression.
 // The class can be used to approximate PDF together with TKDTree or for
 // general regression when the data points are given.
@@ -42,7 +42,7 @@ private:
 //__________________________________________________________________
 Bool_t TKDPDF::GetDataPoint(Int_t n, Float_t *p) const
 {
-       if(n < 0 || n >= fNpoints) return kFALSE;
+       if(n < 0 || n >= fNPoints) return kFALSE;
        if(!fData) return kFALSE;
                
        for(int i=0; i<fNDim; i++) p[i] = fData[i][n];
@@ -52,7 +52,7 @@ Bool_t        TKDPDF::GetDataPoint(Int_t n, Float_t *p) const
 //__________________________________________________________________
 Int_t  TKDPDF::GetNodeIndex(const Float_t *p)
 {
-       return FindNode(p) - fNnodes;
+       return FindNode(p) - fNNodes;
 }
 
 #endif