#include "TKDInterpolator.h"
#include "TLinearFitter.h"
-#include "TVector.h"
#include "TTree.h"
#include "TH2.h"
#include "TObjArray.h"
#include "TObjString.h"
-#include "TPad.h"
#include "TBox.h"
#include "TGraph.h"
#include "TMarker.h"
-#include "TRandom.h"
-#include "TROOT.h"
-
-
+#include "TVectorD.h"
+#include "TMatrixD.h"
ClassImp(TKDInterpolator)
+ClassImp(TKDInterpolator::TKDNodeInfo)
/////////////////////////////////////////////////////////////////////
-// Memory setup of protected data memebers
+// Memory setup of protected data members
// fRefPoints : evaluation point of PDF for each terminal node of underlying KD Tree.
// | 1st terminal node (fNDim point coordinates) | 2nd terminal node (fNDim point coordinates) | ...
//
// fRefValues : evaluation value/error of PDF for each terminal node of underlying KD Tree.
// | 1st terminal node (value) | 2nd terminal node (value) | ... | 1st terminal node (error) | 2nd terminal node (error) | ...
+//
+// status = |0|0|0|0|0|1(tri-cubic weights)|1(STORE)|1 INT(0 COG )|
/////////////////////////////////////////////////////////////////////
+//_________________________________________________________________
+TKDInterpolator::TKDNodeInfo::TKDNodeInfo(const Int_t dim):
+ fNDim(dim)
+ ,fRefPoint(0x0)
+ ,fRefValue(0.)
+ ,fCov(0x0)
+ ,fPar(0x0)
+{
+ if(fNDim) Build(dim);
+}
+
+//_________________________________________________________________
+TKDInterpolator::TKDNodeInfo::~TKDNodeInfo()
+{
+ if(fRefPoint) delete [] fRefPoint;
+ if(fCov){
+ delete fPar;
+ delete fCov;
+ }
+}
+
+//_________________________________________________________________
+void TKDInterpolator::TKDNodeInfo::Build(const Int_t dim)
+{
+// Allocate/Reallocate space for this node.
+
+ if(!dim) return;
+
+ fNDim = dim;
+ Int_t lambda = Int_t(1 + fNDim + .5*fNDim*(fNDim+1));
+ if(fRefPoint) delete [] fRefPoint;
+ fRefPoint = new Float_t[fNDim];
+ if(fCov){
+ fCov->ResizeTo(lambda, lambda);
+ fPar->ResizeTo(lambda);
+ }
+ return;
+}
+
+//_________________________________________________________________
+void TKDInterpolator::TKDNodeInfo::Store(const TVectorD &par, const TMatrixD &cov)
+{
+ if(!fCov){
+ fCov = new TMatrixD(cov.GetNrows(), cov.GetNrows());
+ fPar = new TVectorD(par.GetNrows());
+ }
+ (*fPar) = par;
+ (*fCov) = cov;
+}
+
+//_________________________________________________________________
+Double_t TKDInterpolator::TKDNodeInfo::CookPDF(const Double_t *point, Double_t &result, Double_t &error)
+{
+// Recalculate the PDF for one node from the results of interpolation (parameters and covariance matrix)
+
+ if(fNDim>10) return 0.; // support only up to 10 dimensions
+
+ Int_t lambda = 1 + fNDim + (fNDim*(fNDim+1)>>1);
+ Double_t fdfdp[66];
+ Int_t ipar = 0;
+ fdfdp[ipar++] = 1.;
+ for(int idim=0; idim<fNDim; idim++){
+ fdfdp[ipar++] = point[idim];
+ for(int jdim=idim; jdim<fNDim; jdim++) fdfdp[ipar++] = point[idim]*point[jdim];
+ }
+
+ // calculate estimation
+ result =0.; error = 0.;
+ for(int i=0; i<lambda; i++){
+ result += fdfdp[i]*(*fPar)(i);
+ for(int j=0; j<lambda; j++) error += fdfdp[i]*fdfdp[j]*(*fCov)(i,j);
+ }
+ error = TMath::Sqrt(error);
+
+ //printf("TKDNodeInfo::CookPDF() : %6.3f +- %6.3f\n", result, error);
+
+ return 0.;
+}
+
+
//_________________________________________________________________
TKDInterpolator::TKDInterpolator() : TKDTreeIF()
,fNTNodes(0)
- ,fRefPoints(0x0)
- ,fRefValues(0x0)
+ ,fTNodes(0x0)
+ ,fStatus(4)
+ ,fLambda(0)
,fDepth(-1)
- ,fTmpPoint(0x0)
+ ,fAlpha(.5)
+ ,fRefPoints(0x0)
+ ,fBuffer(0x0)
,fKDhelper(0x0)
,fFitter(0x0)
{
//_________________________________________________________________
TKDInterpolator::TKDInterpolator(Int_t npoints, Int_t ndim, UInt_t bsize, Float_t **data) : TKDTreeIF(npoints, ndim, bsize, data)
- ,fNTNodes(GetNTerminalNodes())
- ,fRefPoints(0x0)
- ,fRefValues(0x0)
+ ,fNTNodes(GetNTNodes())
+ ,fTNodes(0x0)
+ ,fStatus(4)
+ ,fLambda(0)
,fDepth(-1)
- ,fTmpPoint(0x0)
+ ,fAlpha(.5)
+ ,fRefPoints(0x0)
+ ,fBuffer(0x0)
,fKDhelper(0x0)
,fFitter(0x0)
{
-// Wrapper constructor for the similar TKDTree one.
-
+// Wrapper constructor for the TKDTree.
+
Build();
}
//_________________________________________________________________
-TKDInterpolator::TKDInterpolator(TTree *t, const Char_t *var, const Char_t *cut, UInt_t bsize) : TKDTreeIF()
+TKDInterpolator::TKDInterpolator(TTree *t, const Char_t *var, const Char_t *cut, UInt_t bsize, Long64_t nentries, Long64_t firstentry) : TKDTreeIF()
,fNTNodes(0)
- ,fRefPoints(0x0)
- ,fRefValues(0x0)
+ ,fTNodes(0x0)
+ ,fStatus(4)
+ ,fLambda(0)
,fDepth(-1)
- ,fTmpPoint(0x0)
+ ,fAlpha(.5)
+ ,fRefPoints(0x0)
+ ,fBuffer(0x0)
,fKDhelper(0x0)
,fFitter(0x0)
{
//
TObjArray *vars = TString(var).Tokenize(":");
- fNDim = vars->GetEntriesFast();
+ fNDim = vars->GetEntriesFast(); fNDimm = 2*fNDim;
if(fNDim > 6/*kDimMax*/) Warning("TKDInterpolator(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"))){
- Warning("TKDInterpolator(TTree*, const Char_t, const Char_t, UInt_t)", Form("Can not access data for %s", ((TObjString*)(*vars)[idim])->GetName() ));
+ if(!(np = t->Draw(((TObjString*)(*vars)[idim])->GetName(), cut, "goff", nentries, firstentry))){
+ Warning("TKDInterpolator(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("TKDInterpolator(TTree*, const Char_t, const Char_t, UInt_t)", Form("Allocating %d data points in %d dimensions.", fNpoints, fNDim));
- //Float_t *mem = new Float_t[fNDim*fNpoints];
+ //Info("TKDInterpolator(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]; //&mem[idim*fNpoints];
+ for(int idim=0; idim<fNDim; idim++) fData[idim] = new Float_t[fNpoints];
kDataOwner = kTRUE;
}
v = t->GetV1();
for(int ip=0; ip<fNpoints; ip++) fData[idim][ip] = (Float_t)v[ip];
}
TKDTreeIF::Build();
- fNTNodes = GetNTerminalNodes();
Build();
}
{
if(fFitter) delete fFitter;
if(fKDhelper) delete fKDhelper;
- if(fTmpPoint) delete [] fTmpPoint;
+ if(fBuffer) delete [] fBuffer;
if(fRefPoints){
for(int idim=0; idim<fNDim; idim++) delete [] fRefPoints[idim] ;
delete [] fRefPoints;
}
- if(fRefValues) delete [] fRefValues;
+ if(fTNodes) delete [] fTNodes;
}
//_________________________________________________________________
// - estimation points
// - corresponding PDF values
+ fNTNodes = TKDTreeIF::GetNTNodes();
if(!fBoundaries) MakeBoundaries();
+ fLambda = 1 + fNDim + (fNDim*(fNDim+1)>>1);
+ //printf("after MakeBoundaries() %d\n", memory());
// allocate memory for data
- fRefValues = new Float_t[fNTNodes];
- fRefPoints = new Float_t*[fNDim];
- for(int id=0; id<fNDim; id++){
- fRefPoints[id] = new Float_t[fNTNodes];
- for(int in=0; in<fNTNodes; in++) fRefPoints[id][in] = 0.;
- }
+ fTNodes = new TKDNodeInfo[fNTNodes];
+ for(int in=0; in<fNTNodes; in++) fTNodes[in].Build(fNDim);
+ //printf("after BuildNodes() %d\n", memory());
Float_t *bounds = 0x0;
Int_t *indexPoints;
for(int inode=0, tnode = fNnodes; inode<fNTNodes-1; inode++, tnode++){
- fRefValues[inode] = Float_t(fBucketSize)/fNpoints;
+ fTNodes[inode].fRefValue = Float_t(fBucketSize)/fNpoints;
bounds = GetBoundary(tnode);
- for(int idim=0; idim<fNDim; idim++) fRefValues[inode] /= (bounds[2*idim+1] - bounds[2*idim]);
-
+ for(int idim=0; idim<fNDim; idim++) fTNodes[inode].fRefValue /= (bounds[2*idim+1] - bounds[2*idim]);
+
indexPoints = GetPointsIndexes(tnode);
// loop points in this terminal node
for(int idim=0; idim<fNDim; idim++){
- for(int ip = 0; ip<fBucketSize; ip++) fRefPoints[idim][inode] += fData[idim][indexPoints[ip]];
- fRefPoints[idim][inode] /= fBucketSize;
+ fTNodes[inode].fRefPoint[idim] = 0.;
+ for(int ip = 0; ip<fBucketSize; ip++){
+/* printf("\t\tindex[%d] = %d %f\n", ip, indexPoints[ip], fData[idim][indexPoints[ip]]);*/
+ fTNodes[inode].fRefPoint[idim] += fData[idim][indexPoints[ip]];
+ }
+ fTNodes[inode].fRefPoint[idim] /= fBucketSize;
}
}
Int_t counts = fNpoints%fBucketSize;
counts = counts ? counts : fBucketSize;
Int_t inode = fNTNodes - 1, tnode = inode + fNnodes;
- fRefValues[inode] = Float_t(counts)/fNpoints;
+ fTNodes[inode].fRefValue = Float_t(counts)/fNpoints;
bounds = GetBoundary(tnode);
- for(int idim=0; idim<fNDim; idim++) fRefValues[inode] /= (bounds[2*idim+1] - bounds[2*idim]);
+ for(int idim=0; idim<fNDim; idim++) fTNodes[inode].fRefValue /= (bounds[2*idim+1] - bounds[2*idim]);
- indexPoints = GetPointsIndexes(tnode);
// loop points in this terminal node
+ indexPoints = GetPointsIndexes(tnode);
for(int idim=0; idim<fNDim; idim++){
- for(int ip = 0; ip<counts; ip++) fRefPoints[idim][inode] += fData[idim][indexPoints[ip]];
- fRefPoints[idim][inode] /= counts;
+ fTNodes[inode].fRefPoint[idim] = 0.;
+ for(int ip = 0; ip<counts; ip++) fTNodes[inode].fRefPoint[idim] += fData[idim][indexPoints[ip]];
+ fTNodes[inode].fRefPoint[idim] /= counts;
+ }
+}
+
+//__________________________________________________________________
+void TKDInterpolator::GetStatus()
+{
+// Prints the status of the interpolator
+
+ printf("Interpolator Status :\n");
+ printf(" Method : %s\n", fStatus&1 ? "INT" : "COG");
+ printf(" Store : %s\n", fStatus&2 ? "YES" : "NO");
+ printf(" Weights: %s\n", fStatus&4 ? "YES" : "NO");
+ return;
+
+ printf("fNTNodes %d\n", fNTNodes); //Number of evaluation data points
+ for(int i=0; i<fNTNodes; i++){
+ printf("%d ", i);
+ for(int idim=0; idim<fNDim; idim++) printf("%f ", fTNodes[i].fRefPoint[idim]);
+ printf("[%f] %s\n", fTNodes[i].fRefValue, fTNodes[i].fCov ? "true" : "false");
+ printf("Fit parameters : ");
+ if(!fTNodes[i].fPar){
+ printf("Not defined.\n");
+ continue;
+ }
+ for(int ip=0; ip<3; ip++) printf("p%d[%f] ", ip, (*fTNodes[i].fPar)(ip));
+ printf("\n");
}
}
//_________________________________________________________________
-Double_t TKDInterpolator::Eval(const Double_t *point, Int_t npoints)
+Double_t TKDInterpolator::Eval(const Double_t *point, Double_t &result, Double_t &error, Bool_t force)
{
-// Evaluate PDF at k-dimensional position "point". The initial number of
-// neighbour estimation points is set to "npoints"
+// Evaluate PDF for "point". The result is returned in "result" and error in "error". The function returns the chi2 of the fit.
+//
+// Observations:
+//
+// 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<fNDim; idim++) pointF[idim] = (Float_t)point[idim];
+ Int_t node = FindNode(pointF) - fNnodes;
+ if((fStatus&1) && fTNodes[node].fCov && !force) return fTNodes[node].CookPDF(point, result, error);
+
+ // Allocate memory
+ if(!fBuffer) fBuffer = new Double_t[2*fLambda];
+ if(!fKDhelper){
+ fRefPoints = new Float_t*[fNDim];
+ for(int id=0; id<fNDim; id++){
+ fRefPoints[id] = new Float_t[fNTNodes];
+ for(int in=0; in<fNTNodes; in++) fRefPoints[id][in] = fTNodes[in].fRefPoint[id];
+ }
+// for(int in=0; in<fNTNodes; in++){
+// printf("%3d ", in);
+// for(int id=0; id<fNDim; id++) printf("%6.3f ", fTNodes[in].fRefPoint[id]/*fRefPoints[id][in]*/);
+// printf("\n");
+// }
+ fKDhelper = new TKDTreeIF(fNTNodes, fNDim, 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
- if(!fTmpPoint) fTmpPoint = new Double_t[fNDim];
- if(!fKDhelper) fKDhelper = new TKDTreeIF(GetNTerminalNodes(), fNDim, npoints, fRefPoints);
- if(!fFitter){
- // generate parabolic for nD
-
- // calculate number of parameters in the parabolic expresion
- Int_t lambda = 1 + fNDim + fNDim*(fNDim+1)/2;
- //Float_t alpha = Float_t(2*lambda + 1) / fNTNodes; // the bandwidth or smoothing parameter
- TString formula("1");
- for(int idim=0; idim<fNDim; idim++){
- formula += Form("++x[%d]", idim);
- for(int jdim=idim; jdim<fNDim; jdim++) formula += Form("++x[%d]*x[%d]", idim, jdim);
- }
- fFitter = new TLinearFitter(lambda, formula.Data());
- Info("Eval(const Double_t*, Int_t)", Form("Using %s for local interpolation.", formula.Data()));
- }
- Float_t pointF[50];
- for(int idim=0; idim<fNDim; idim++) pointF[idim] = point[idim];
- Int_t istart = 0;
- Int_t *index;
- Float_t dist, d0, w0, w;
- Double_t uncertainty = TMath::Sqrt(1./fBucketSize);
- fFitter->ClearPoints();
+ 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
+ Double_t sig // bucket error
+ = TMath::Sqrt(1./fBucketSize);
+
do{
+ // find nearest neighbors
+ for(int idim=0; idim<fNDim; 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<fNDim; idim++) printf("%f ", point[idim]);
printf("\n");
return -1;
}
- for(int in=istart; in<npoints; in++){
- //printf("%d index[%2d] x(", in, index[in]);
- d0 = 0.;
- for(int idim=0; idim<fNDim; idim++){
- fTmpPoint[idim] = fRefPoints[idim][index[in]];
- //printf("%6.4f ", fTmpPoint[idim]);
- d0 += TMath::Abs(fTmpPoint[idim] - point[idim]);
+ // add points to fitter
+ fFitter->ClearPoints();
+ TKDNodeInfo *node = 0x0;
+ for(int in=0; in<npoints; in++){
+ node = &fTNodes[index[in]];
+ if(fStatus&1){ // INT
+ Float_t *bounds = GetBoundary(FindNode(node->fRefPoint));
+ ipar = 0;
+ for(int idim=0; idim<fNDim; 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<fNDim; jdim++) fBuffer[ipar++] = (bounds[2*idim] + bounds[2*idim+1]) * (bounds[2*jdim] + bounds[2*jdim+1]) * .25;
+ }
+ } else { // COG
+ Float_t *p = node->fRefPoint;
+ ipar = 0;
+ for(int idim=0; idim<fNDim; idim++){
+ fBuffer[ipar++] = p[idim];
+ for(int jdim=idim; jdim<fNDim; jdim++) fBuffer[ipar++] = p[idim]*p[jdim];
+ }
}
- d0 /= dist;
- w0 = (1. - d0*d0*d0);
- w = w0*w0*w0;
- //printf(") f = %f [%f] d0 = %6.4f w = %6.4f \n", fRefValues[index[in]], TMath::Log(fRefValues[index[in]]), d0, w);
- fFitter->AddPoint(fTmpPoint, TMath::Log(fRefValues[index[in]]), uncertainty/w);
+ // 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.;
+
+ //for(int idim=0; idim<fNDim; idim++) printf("%f ", fBuffer[idim]);
+ //printf("\nd[%f] w[%f] sig[%f]\n", d, w, sig);
+ fFitter->AddPoint(fBuffer, node->fRefValue, node->fRefValue*sig/w);
}
- istart = npoints;
npoints += 4;
} while(fFitter->Eval());
- // calculate evaluation
- Int_t ipar = 0;
- Double_t result = fFitter->GetParameter(ipar++);
+ // 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) fTNodes[node].Store(par, cov);
+
+ // Build df/dpi|x values
+ Double_t *fdfdp = &fBuffer[fLambda];
+ ipar = 0;
+ fdfdp[ipar++] = 1.;
for(int idim=0; idim<fNDim; idim++){
- result += fFitter->GetParameter(ipar++)*point[idim];
- for(int jdim=idim; jdim<fNDim; jdim++) result += fFitter->GetParameter(ipar++)*point[idim]*point[jdim];
+ fdfdp[ipar++] = point[idim];
+ for(int jdim=idim; jdim<fNDim; jdim++) fdfdp[ipar++] = point[idim]*point[jdim];
}
- //printf("\tResult : %f [%f]\n", TMath::Exp(result), result);
- return TMath::Exp(result);
-}
+ // 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;
+}
//_________________________________________________________________
void TKDInterpolator::DrawNodes(UInt_t ax1, UInt_t ax2, Int_t depth)
//printf("depth %d nodes %d\n", depth, nnodes);
- TH2 *h2 = 0x0;
- if(!(h2 = (TH2S*)gROOT->FindObject("hNodes"))) h2 = new TH2S("hNodes", "", 100, fRange[2*ax1], fRange[2*ax1+1], 100, fRange[2*ax2], fRange[2*ax2+1]);
+ TH2 *h2 = new TH2S("hNodes", "", 100, fRange[2*ax1], fRange[2*ax1+1], 100, fRange[2*ax2], fRange[2*ax2+1]);
h2->GetXaxis()->SetTitle(Form("x_{%d}", ax1));
h2->GetYaxis()->SetTitle(Form("x_{%d}", ax2));
h2->Draw();
- const Float_t border = 0.;//1.E-4;
- TBox *node_array = new TBox[nnodes], *node;
+ const Float_t kBorder = 0.;//1.E-4;
+ TBox *nodeArray = new TBox[nnodes], *node;
Float_t *bounds = 0x0;
nnodes = 0;
for(int inode = 0; inode <= 2*fNnodes; inode++){
if(!IsTerminal(inode)) continue;
} else if((inode+1) >> depth != 1) continue;
- node = &node_array[nnodes++];
+ node = &nodeArray[nnodes++];
//node = new TBox(bounds[2*ax1]+border, bounds[2*ax2]+border, bounds[2*ax1+1]-border, bounds[2*ax2+1]-border);
node->SetFillStyle(3002);
- node->SetFillColor(50+Int_t(gRandom->Uniform()*50.));
+ node->SetFillColor(50+inode/*Int_t(gRandom->Uniform()*50.)*/);
bounds = GetBoundary(inode);
- node->DrawBox(bounds[2*ax1]+border, bounds[2*ax2]+border, bounds[2*ax1+1]-border, bounds[2*ax2+1]-border);
+ node->DrawBox(bounds[2*ax1]+kBorder, bounds[2*ax2]+kBorder, bounds[2*ax1+1]-kBorder, bounds[2*ax2+1]-kBorder);
}
if(depth != -1) return;
// Draw reference points
- TGraph *ref = new TGraph(GetNTerminalNodes());
+ TGraph *ref = new TGraph(fNTNodes);
ref->SetMarkerStyle(3);
ref->SetMarkerSize(.7);
ref->SetMarkerColor(2);
- for(int inode = 0; inode < GetNTerminalNodes(); inode++) ref->SetPoint(inode, fRefPoints[ax1][inode], fRefPoints[ax2][inode]);
+ for(int inode = 0; inode < fNTNodes; inode++) ref->SetPoint(inode, fTNodes[inode].fRefPoint[ax1], fTNodes[inode].fRefPoint[ax2]);
ref->Draw("p");
return;
}
// This function creates some graphical objects
// but don't delete it. Abusing this function may cause memory leaks !
- if(tnode < 0 || tnode >= GetNTerminalNodes()){
+ if(tnode < 0 || tnode >= fNTNodes){
Warning("DrawNode()", Form("Terminal node %d outside defined range.", tnode));
return;
}
for(int ip = 0; ip<nPoints; ip++) g->SetPoint(ip, fData[ax1][index[ip]], fData[ax2][index[ip]]);
// draw estimation point
- TMarker *m=new TMarker(fRefPoints[ax1][inode], fRefPoints[ax2][inode], 20);
+ TMarker *m=new TMarker(fTNodes[inode].fRefPoint[ax1], fTNodes[inode].fRefPoint[ax2], 20);
m->SetMarkerColor(2);
m->SetMarkerSize(1.7);
TBox *n = new TBox(bounds[2*ax1], bounds[2*ax2], bounds[2*ax1+1], bounds[2*ax2+1]);
n->SetFillStyle(0);
- if(gPad) gPad->Clear();
g->Draw("ap");
m->Draw();
n->Draw();
return;
}
+
+//__________________________________________________________________
+void TKDInterpolator::SetInterpolationMethod(const Bool_t on)
+{
+// Set interpolation bit to "on".
+
+ if(on) fStatus += fStatus&1 ? 0 : 1;
+ else fStatus += fStatus&1 ? -1 : 0;
+}
+
+
+//_________________________________________________________________
+void TKDInterpolator::SetStore(const Bool_t on)
+{
+// Set store bit to "on"
+
+ if(on) fStatus += fStatus&2 ? 0 : 2;
+ else fStatus += fStatus&2 ? -2 : 0;
+}
+
+//_________________________________________________________________
+void TKDInterpolator::SetWeights(const Bool_t on)
+{
+// Set weights bit to "on"
+
+ if(on) fStatus += fStatus&4 ? 0 : 4;
+ else fStatus += fStatus&4 ? -4 : 0;
+}