[u/mrichter/AliRoot.git] / STAT / TKDInterpolatorBase.cxx

#include "TKDInterpolatorBase.h"
#include "TKDNodeInfo.h"
#include "TKDTree.h"

#include "TROOT.h"
#include "TClonesArray.h"
#include "TLinearFitter.h"
#include "TTree.h"
#include "TH2.h"
#include "TObjArray.h"
#include "TObjString.h"
#include "TMath.h"
#include "TVectorD.h"
#include "TMatrixD.h"

ClassImp(TKDInterpolatorBase)

/////////////////////////////////////////////////////////////////////
// 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 )|
/////////////////////////////////////////////////////////////////////


//_________________________________________________________________
TKDInterpolatorBase::TKDInterpolatorBase(Int_t dim) :
  fNSize(dim)
  ,fNodes(NULL)
  ,fNodesDraw(NULL)
  ,fStatus(0)
  ,fLambda(1 + dim + (dim*(dim+1)>>1))
  ,fDepth(-1)
  ,fAlpha(.5)
  ,fRefPoints(NULL)
  ,fBuffer(NULL)
  ,fKDhelper(NULL)
  ,fFitter(NULL)
{
// Default constructor. To be used with care since in this case building
// of data structure is completly left to the user responsability.
  UseWeights();
}

//_________________________________________________________________
Bool_t TKDInterpolatorBase::Build(Int_t n)
{
  // allocate memory for data
  if(Int_t((1.+fAlpha)*fLambda) > n){ // check granularity
    Error("TKDInterpolatorBase::Build()", Form("Minimum number of points [%d] needed for interpolation exceeds number of evaluation points [%d]. Please increase granularity.", Int_t((1.+fAlpha)*fLambda), n));
    return kFALSE;
  }

  if(fNodes){
    Warning("TKDInterpolatorBase::Build()", "Data already allocated.");
    fNodes->Delete();
  } else {
    fNodes = new TClonesArray("TKDNodeInfo", n); 
    fNodes->SetOwner();
  }

  for(int in=0; in<n; in++) new ((*fNodes)[in]) TKDNodeInfo(fNSize);

  return kTRUE;
}

//_________________________________________________________________
Bool_t TKDInterpolatorBase::Bootstrap()
{
  if(!fNodes){
    Error("TKDInterpolatorBase::Bootstrap()", "Nodes missing. Nothing to bootstrap from.");
    return kFALSE;
  }
  Int_t in = GetNTNodes(); TKDNodeInfo *n(NULL);
  while(in--){ 
    if(!(n=(TKDNodeInfo*)(*fNodes)[in])){
      Error("TKDInterpolatorBase::Bootstrap()", Form("Node @ %d missing.", in));
      return kFALSE;
    }
    n->Bootstrap();
    if(!fNSize) fNSize  = n->GetDimension();
    //n->SetNode(fNSize, ...);
  }
  fLambda = n->GetNpar();
  return kTRUE;
}

//_________________________________________________________________
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(fNodes){ 
    fNodes->Delete();
    delete fNodes;
  }
  if(fNodesDraw) delete [] fNodesDraw;

  TH2 *h2=NULL;
  if((h2 = (TH2S*)gROOT->FindObject("hKDnodes"))) delete h2;
}


//__________________________________________________________________
Bool_t	TKDInterpolatorBase::GetCOGPoint(Int_t inode, Float_t *&coord, Float_t &val, Float_t &err) const
{
  if(inode < 0 || inode > GetNTNodes()) return kFALSE;

  TKDNodeInfo *node = (TKDNodeInfo*)(*fNodes)[inode];
  coord = &(node->Data()[0]);
  val = node->Val()[0];
  err = node->Val()[1];
  return kTRUE;
}

//_________________________________________________________________
TKDNodeInfo* TKDInterpolatorBase::GetNodeInfo(Int_t inode) const
{
  if(!fNodes || inode >= GetNTNodes()) return NULL;
  return (TKDNodeInfo*)(*fNodes)[inode];
}

//_________________________________________________________________
Int_t TKDInterpolatorBase::GetNTNodes() const 
{
  return fNodes?fNodes->GetEntriesFast():0;
}

//_________________________________________________________________
Bool_t TKDInterpolatorBase::GetRange(Int_t ax, Float_t &min, Float_t &max) const
{
  if(!fNodes) return kFALSE;
  Int_t ndim = ((TKDNodeInfo*)(*fNodes)[0])->GetDimension();
  if(ax<0 || ax>=ndim){
    min=0.; max=0.;
    return kFALSE;
  }
  min=1.e10; max=-1.e10;
  Float_t axmin, axmax;
  for(Int_t in=GetNTNodes(); in--; ){ 
    TKDNodeInfo *node = (TKDNodeInfo*)((*fNodes)[in]);
    node->GetBoundary(ax, axmin, axmax);
    if(axmin<min) min = axmin;
    if(axmax>max) max = axmax;
  }
  
  return kTRUE;
}

//__________________________________________________________________
void TKDInterpolatorBase::GetStatus(Option_t *opt)
{
// Prints the status of the interpolator

  printf("Interpolator Status[%d] :\n", fStatus);
  printf("  Dim    : %d [%d]\n", fNSize, fLambda);
  printf("  Method : %s\n", UseCOG() ? "COG" : "INT");
  printf("  Store  : %s\n", HasStore() ? "YES" : "NO");
  printf("  Weights: %s\n", UseWeights() ? "YES" : "NO");
  
  if(strcmp(opt, "all") != 0 ) return;
  printf("GetNTNodes() %d\n", GetNTNodes());        //Number of evaluation data points
  for(int i=0; i<GetNTNodes(); i++){
    TKDNodeInfo *node = (TKDNodeInfo*)(*fNodes)[i]; 
    printf("%d ", i); node->Print();
  }
}

//_________________________________________________________________
Double_t TKDInterpolatorBase::Eval(const Double_t *point, Double_t &result, Double_t &error, Bool_t force)
{
// 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<fNSize; idim++) pointF[idim] = (Float_t)point[idim];
  Int_t nodeIndex = GetNodeIndex(pointF);
  if(nodeIndex<0){ 
    Error("TKDInterpolatorBase::Eval()", "Can not retrive node for data point.");      
    result = 0.;   
    error = 1.E10;
    return 0.;
  }
  TKDNodeInfo *node = (TKDNodeInfo*)(*fNodes)[nodeIndex];
  if(node->Par() && !force){ 
    //printf("Node @ %d\n", nodeIndex); node->Print("a");
    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[GetNTNodes()];
      for(int in=0; in<GetNTNodes(); in++) fRefPoints[id][in] = ((TKDNodeInfo*)(*fNodes)[in])->Data()[id];
    }
    Info("TKDInterpolatorBase::Eval()", Form("Build TKDTree(%d, %d, %d)", GetNTNodes(), fNSize, kNhelper));
    fKDhelper = new TKDTreeIF(GetNTNodes(), fNSize, kNhelper, fRefPoints);
    fKDhelper->Build();
    fKDhelper->MakeBoundariesExact();
  }
  if(!fFitter) fFitter = new TLinearFitter(fLambda, Form("hyp%d", fLambda-1));
  
  // generate parabolic for nD
  //Float_t alpha = Float_t(2*lambda + 1) / GetNTNodes(); // the bandwidth or smoothing parameter
  //Int_t npoints = Int_t(alpha * GetNTNodes());
  //printf("Params : %d NPoints %d\n", lambda, npoints);
  // prepare workers

  Int_t ipar,    // local looping variable
        npoints_new = Int_t((1.+fAlpha)*fLambda),
        npoints(0); // number of data points used for interpolation
  Int_t *index = new Int_t[2*npoints_new];  // indexes of NN 
  Float_t *dist = new Float_t[2*npoints_new], // distances of NN
          d,     // NN normalized distance
          w0,    // work
          w;     // tri-cubic weight function

  Bool_t kDOWN = kFALSE;
  do{
    if(npoints){
      Info("TKDInterpolatorBase::Eval()", Form("Interpolation failed. Trying to increase the number of interpolation points from %d to %d.", npoints, npoints_new));
    }
    if(npoints == npoints_new){
      Error("TKDInterpolatorBase::Eval()", Form("Interpolation failed and number of interpolation points (%d) Can not be increased further.", npoints));
      result = 0.;
      error = 1.E10;
      // clean memory
      delete [] dist; delete [] index;
      return 0.;
    } else npoints = npoints_new;
    if(npoints > GetNTNodes()){
      Warning("TKDInterpolatorBase::Eval()", Form("The number of interpolation points requested (%d) exceeds number of PDF values (%d). Downscale.", npoints, GetNTNodes()));
      npoints = GetNTNodes();
      kDOWN = kTRUE;
    }

    // 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 = NULL;
    for(int in=0; in<npoints; in++){
      tnode = (TKDNodeInfo*)(*fNodes)[index[in]];
      //tnode->Print();
      if(UseCOG()){ // 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];
        }
      } else { // 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;
        }
      }

      // calculate tri-cubic weighting function
      if(UseWeights()){
        d = dist[in]/dist[npoints];
        w0 = (1. - d*d*d); w = w0*w0*w0;
        if(w<1.e-30) continue;
      } else w = 1.;
      
//       printf("%2d d[%f] w[%f] x[", index[in], d, w);
//       for(int idim=0; idim<fLambda-1; idim++) printf("%f ", fBuffer[idim]);
//       printf("]\n");  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_new = npoints+ (kDOWN ? 0 : kdN);
  } 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
  node->Store(&par, HasStore()?&cov:NULL);
    
  // 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;
}

//_________________________________________________________________
void TKDInterpolatorBase::DrawProjection(UInt_t ax1, UInt_t ax2)
{
// Draw nodes structure projected on plane "ax1:ax2". The parameter
// "depth" specifies the bucket size per node. If depth == -1 draw only
// terminal nodes and evaluation points (default -1 i.e. bucket size per node equal bucket size specified by the user)
//
  
  Float_t ax1min, ax1max, ax2min, ax2max;
  GetRange(ax1, ax1min, ax1max);
  GetRange(ax2, ax2min, ax2max);
  TH2 *h2 = NULL;
  if(!(h2 = (TH2S*)gROOT->FindObject("hKDnodes"))){
    h2 = new TH2S("hKDnodes", "", 100, ax1min, ax1max, 100, ax2min, ax2max);
  }
  h2->GetXaxis()->SetRangeUser(ax1min, ax1max);
  h2->GetXaxis()->SetTitle(Form("x_{%d}", ax1));
  h2->GetYaxis()->SetRangeUser(ax2min, ax2max);
  h2->GetYaxis()->SetTitle(Form("x_{%d}", ax2));
  h2->Draw();


  if(!fNodesDraw) fNodesDraw = new TKDNodeInfo::TKDNodeDraw[GetNTNodes()]; 
  TKDNodeInfo::TKDNodeDraw *box = NULL;
  for(Int_t in=GetNTNodes(); in--; ){ 
    box = &(fNodesDraw[in]);
    box->SetNode((TKDNodeInfo*)((*fNodes)[in]), fNSize, ax1, ax2);
    box->Draw();
  }

  return;
}

//_________________________________________________________________
void TKDInterpolatorBase::SetAlpha(Float_t a)
{
  if(a<0.5){ 
    Warning("TKDInterpolatorBase::SetAlpha()", "The scale parameter has to be larger than 0.5");
    fAlpha = 0.5;
    return;
  }
  // check value
  if(Int_t((a+1.)*fLambda) > GetNTNodes()){
    fAlpha = TMath::Max(0.5, Float_t(GetNTNodes())/fLambda-1.);
    Warning("TKDInterpolatorBase::SetAlpha()", Form("Interpolation neighborhood  exceeds number of evaluation points. Downscale alpha to %f", fAlpha));
    printf("n[%d] nodes[%d]\n", Int_t((fAlpha+1.)*fLambda), GetNTNodes());
    return;
  }
  fAlpha = a;
  return;
}
Commit	Line	Data
	1	#include "TKDInterpolatorBase.h"
	2	#include "TKDNodeInfo.h"
	3	#include "TKDTree.h"
	4
	5	#include "TROOT.h"
	6	#include "TClonesArray.h"
	7	#include "TLinearFitter.h"
	8	#include "TTree.h"
	9	#include "TH2.h"
	10	#include "TObjArray.h"
	11	#include "TObjString.h"
	12	#include "TMath.h"
	13	#include "TVectorD.h"
	14	#include "TMatrixD.h"
	15
	16	ClassImp(TKDInterpolatorBase)
	17
	18	/////////////////////////////////////////////////////////////////////
	19	// Memory setup of protected data members
	20	// fRefPoints : evaluation point of PDF for each terminal node of underlying KD Tree.
	21	// \| 1st terminal node (fNDim point coordinates) \| 2nd terminal node (fNDim point coordinates) \| ...
	22	//
	23	// fRefValues : evaluation value/error of PDF for each terminal node of underlying KD Tree.
	24	// \| 1st terminal node (value) \| 2nd terminal node (value) \| ... \| 1st terminal node (error) \| 2nd terminal node (error) \| ...
	25	//
	26	// status = \|0\|0\|0\|0\|0\|1(tri-cubic weights)\|1(STORE)\|1 INT(0 COG )\|
	27	/////////////////////////////////////////////////////////////////////
	28
	29
	30	//_________________________________________________________________
	31	TKDInterpolatorBase::TKDInterpolatorBase(Int_t dim) :
	32	fNSize(dim)
	33	,fNodes(NULL)
	34	,fNodesDraw(NULL)
	35	,fStatus(0)
	36	,fLambda(1 + dim + (dim*(dim+1)>>1))
	37	,fDepth(-1)
	38	,fAlpha(.5)
	39	,fRefPoints(NULL)
	40	,fBuffer(NULL)
	41	,fKDhelper(NULL)
	42	,fFitter(NULL)
	43	{
	44	// Default constructor. To be used with care since in this case building
	45	// of data structure is completly left to the user responsability.
	46	UseWeights();
	47	}
	48
	49	//_________________________________________________________________
	50	Bool_t TKDInterpolatorBase::Build(Int_t n)
	51	{
	52	// allocate memory for data
	53	if(Int_t((1.+fAlpha)*fLambda) > n){ // check granularity
	54	Error("TKDInterpolatorBase::Build()", Form("Minimum number of points [%d] needed for interpolation exceeds number of evaluation points [%d]. Please increase granularity.", Int_t((1.+fAlpha)*fLambda), n));
	55	return kFALSE;
	56	}
	57
	58	if(fNodes){
	59	Warning("TKDInterpolatorBase::Build()", "Data already allocated.");
	60	fNodes->Delete();
	61	} else {
	62	fNodes = new TClonesArray("TKDNodeInfo", n);
	63	fNodes->SetOwner();
	64	}
	65
	66	for(int in=0; in<n; in++) new ((*fNodes)[in]) TKDNodeInfo(fNSize);
	67
	68	return kTRUE;
	69	}
	70
	71	//_________________________________________________________________
	72	Bool_t TKDInterpolatorBase::Bootstrap()
	73	{
	74	if(!fNodes){
	75	Error("TKDInterpolatorBase::Bootstrap()", "Nodes missing. Nothing to bootstrap from.");
	76	return kFALSE;
	77	}
	78	Int_t in = GetNTNodes(); TKDNodeInfo *n(NULL);
	79	while(in--){
	80	if(!(n=(TKDNodeInfo)(fNodes)[in])){
	81	Error("TKDInterpolatorBase::Bootstrap()", Form("Node @ %d missing.", in));
	82	return kFALSE;
	83	}
	84	n->Bootstrap();
	85	if(!fNSize) fNSize = n->GetDimension();
	86	//n->SetNode(fNSize, ...);
	87	}
	88	fLambda = n->GetNpar();
	89	return kTRUE;
	90	}
	91
	92	//_________________________________________________________________
	93	TKDInterpolatorBase::~TKDInterpolatorBase()
	94	{
	95	if(fFitter) delete fFitter;
	96	if(fKDhelper) delete fKDhelper;
	97	if(fBuffer) delete [] fBuffer;
	98
	99	if(fRefPoints){
	100	for(int idim=0; idim<fNSize; idim++) delete [] fRefPoints[idim] ;
	101	delete [] fRefPoints;
	102	}
	103	if(fNodes){
	104	fNodes->Delete();
	105	delete fNodes;
	106	}
	107	if(fNodesDraw) delete [] fNodesDraw;
	108
	109	TH2 *h2=NULL;
	110	if((h2 = (TH2S*)gROOT->FindObject("hKDnodes"))) delete h2;
	111	}
	112
	113
	114	//__________________________________________________________________
	115	Bool_t TKDInterpolatorBase::GetCOGPoint(Int_t inode, Float_t *&coord, Float_t &val, Float_t &err) const
	116	{
	117	if(inode < 0 \|\| inode > GetNTNodes()) return kFALSE;
	118
	119	TKDNodeInfo node = (TKDNodeInfo)(*fNodes)[inode];
	120	coord = &(node->Data()[0]);
	121	val = node->Val()[0];
	122	err = node->Val()[1];
	123	return kTRUE;
	124	}
	125
	126	//_________________________________________________________________
	127	TKDNodeInfo* TKDInterpolatorBase::GetNodeInfo(Int_t inode) const
	128	{
	129	if(!fNodes \|\| inode >= GetNTNodes()) return NULL;
	130	return (TKDNodeInfo)(fNodes)[inode];
	131	}
	132
	133	//_________________________________________________________________
	134	Int_t TKDInterpolatorBase::GetNTNodes() const
	135	{
	136	return fNodes?fNodes->GetEntriesFast():0;
	137	}
	138
	139	//_________________________________________________________________
	140	Bool_t TKDInterpolatorBase::GetRange(Int_t ax, Float_t &min, Float_t &max) const
	141	{
	142	if(!fNodes) return kFALSE;
	143	Int_t ndim = ((TKDNodeInfo)(fNodes)[0])->GetDimension();
	144	if(ax<0 \|\| ax>=ndim){
	145	min=0.; max=0.;
	146	return kFALSE;
	147	}
	148	min=1.e10; max=-1.e10;
	149	Float_t axmin, axmax;
	150	for(Int_t in=GetNTNodes(); in--; ){
	151	TKDNodeInfo node = (TKDNodeInfo)((*fNodes)[in]);
	152	node->GetBoundary(ax, axmin, axmax);
	153	if(axmin<min) min = axmin;
	154	if(axmax>max) max = axmax;
	155	}
	156
	157	return kTRUE;
	158	}
	159
	160	//__________________________________________________________________
	161	void TKDInterpolatorBase::GetStatus(Option_t *opt)
	162	{
	163	// Prints the status of the interpolator
	164
	165	printf("Interpolator Status[%d] :\n", fStatus);
	166	printf(" Dim : %d [%d]\n", fNSize, fLambda);
	167	printf(" Method : %s\n", UseCOG() ? "COG" : "INT");
	168	printf(" Store : %s\n", HasStore() ? "YES" : "NO");
	169	printf(" Weights: %s\n", UseWeights() ? "YES" : "NO");
	170
	171	if(strcmp(opt, "all") != 0 ) return;
	172	printf("GetNTNodes() %d\n", GetNTNodes()); //Number of evaluation data points
	173	for(int i=0; i<GetNTNodes(); i++){
	174	TKDNodeInfo node = (TKDNodeInfo)(*fNodes)[i];
	175	printf("%d ", i); node->Print();
	176	}
	177	}
	178
	179	//_________________________________________________________________
	180	Double_t TKDInterpolatorBase::Eval(const Double_t *point, Double_t &result, Double_t &error, Bool_t force)
	181	{
	182	// Evaluate PDF for "point". The result is returned in "result" and error in "error". The function returns the chi2 of the fit.
	183	//
	184	// Observations:
	185	//
	186	// 1. The default method used for interpolation is kCOG.
	187	// 2. The initial number of neighbors used for the estimation is set to Int(alpha*fLambda) (alpha = 1.5)
	188
	189	Float_t pointF[50]; // local Float_t conversion for "point"
	190	for(int idim=0; idim<fNSize; idim++) pointF[idim] = (Float_t)point[idim];
	191	Int_t nodeIndex = GetNodeIndex(pointF);
	192	if(nodeIndex<0){
	193	Error("TKDInterpolatorBase::Eval()", "Can not retrive node for data point.");
	194	result = 0.;
	195	error = 1.E10;
	196	return 0.;
	197	}
	198	TKDNodeInfo node = (TKDNodeInfo)(*fNodes)[nodeIndex];
	199	if(node->Par() && !force){
	200	//printf("Node @ %d\n", nodeIndex); node->Print("a");
	201	return node->CookPDF(point, result, error);
	202	}
	203
	204	// Allocate memory
	205	if(!fBuffer) fBuffer = new Double_t[2*fLambda];
	206	if(!fKDhelper){
	207	fRefPoints = new Float_t*[fNSize];
	208	for(int id=0; id<fNSize; id++){
	209	fRefPoints[id] = new Float_t[GetNTNodes()];
	210	for(int in=0; in<GetNTNodes(); in++) fRefPoints[id][in] = ((TKDNodeInfo)(fNodes)[in])->Data()[id];
	211	}
	212	Info("TKDInterpolatorBase::Eval()", Form("Build TKDTree(%d, %d, %d)", GetNTNodes(), fNSize, kNhelper));
	213	fKDhelper = new TKDTreeIF(GetNTNodes(), fNSize, kNhelper, fRefPoints);
	214	fKDhelper->Build();
	215	fKDhelper->MakeBoundariesExact();
	216	}
	217	if(!fFitter) fFitter = new TLinearFitter(fLambda, Form("hyp%d", fLambda-1));
	218
	219	// generate parabolic for nD
	220	//Float_t alpha = Float_t(2*lambda + 1) / GetNTNodes(); // the bandwidth or smoothing parameter
	221	//Int_t npoints = Int_t(alpha * GetNTNodes());
	222	//printf("Params : %d NPoints %d\n", lambda, npoints);
	223	// prepare workers
	224
	225	Int_t ipar, // local looping variable
	226	npoints_new = Int_t((1.+fAlpha)*fLambda),
	227	npoints(0); // number of data points used for interpolation
	228	Int_t index = new Int_t[2npoints_new]; // indexes of NN
	229	Float_t dist = new Float_t[2npoints_new], // distances of NN
	230	d, // NN normalized distance
	231	w0, // work
	232	w; // tri-cubic weight function
	233
	234	Bool_t kDOWN = kFALSE;
	235	do{
	236	if(npoints){
	237	Info("TKDInterpolatorBase::Eval()", Form("Interpolation failed. Trying to increase the number of interpolation points from %d to %d.", npoints, npoints_new));
	238	}
	239	if(npoints == npoints_new){
	240	Error("TKDInterpolatorBase::Eval()", Form("Interpolation failed and number of interpolation points (%d) Can not be increased further.", npoints));
	241	result = 0.;
	242	error = 1.E10;
	243	// clean memory
	244	delete [] dist; delete [] index;
	245	return 0.;
	246	} else npoints = npoints_new;
	247	if(npoints > GetNTNodes()){
	248	Warning("TKDInterpolatorBase::Eval()", Form("The number of interpolation points requested (%d) exceeds number of PDF values (%d). Downscale.", npoints, GetNTNodes()));
	249	npoints = GetNTNodes();
	250	kDOWN = kTRUE;
	251	}
	252
	253	// find nearest neighbors
	254	for(int idim=0; idim<fNSize; idim++) pointF[idim] = (Float_t)point[idim];
	255	fKDhelper->FindNearestNeighbors(pointF, npoints+1, index, dist);
	256
	257	// add points to fitter
	258	fFitter->ClearPoints();
	259	TKDNodeInfo *tnode = NULL;
	260	for(int in=0; in<npoints; in++){
	261	tnode = (TKDNodeInfo)(fNodes)[index[in]];
	262	//tnode->Print();
	263	if(UseCOG()){ // COG
	264	Float_t *p = &(tnode->Data()[0]);
	265	ipar = 0;
	266	for(int idim=0; idim<fNSize; idim++){
	267	fBuffer[ipar++] = p[idim];
	268	for(int jdim=idim; jdim<fNSize; jdim++) fBuffer[ipar++] = p[idim]*p[jdim];
	269	}
	270	} else { // INT
	271	Float_t *bounds = &(tnode->Data()[fNSize]);
	272	ipar = 0;
	273	for(int idim=0; idim<fNSize; idim++){
	274	fBuffer[ipar++] = .5(bounds[2idim] + bounds[2*idim+1]);
	275	fBuffer[ipar++] = (bounds[2idim]bounds[2idim] + bounds[2idim] * bounds[2idim+1] + bounds[2idim+1] * bounds[2*idim+1])/3.;
	276	for(int jdim=idim+1; jdim<fNSize; jdim++) fBuffer[ipar++] = (bounds[2idim] + bounds[2idim+1]) * (bounds[2jdim] + bounds[2jdim+1]) * .25;
	277	}
	278	}
	279
	280	// calculate tri-cubic weighting function
	281	if(UseWeights()){
	282	d = dist[in]/dist[npoints];
	283	w0 = (1. - ddd); w = w0w0w0;
	284	if(w<1.e-30) continue;
	285	} else w = 1.;
	286
	287	// printf("%2d d[%f] w[%f] x[", index[in], d, w);
	288	// for(int idim=0; idim<fLambda-1; idim++) printf("%f ", fBuffer[idim]);
	289	// printf("]\n"); printf("v[%f +- %f] (%f, %f)\n", tnode->Val()[0], tnode->Val()[1]/w, tnode->Val()[1], w);
	290	fFitter->AddPoint(fBuffer, tnode->Val()[0], tnode->Val()[1]/w);
	291	}
	292	npoints_new = npoints+ (kDOWN ? 0 : kdN);
	293	} while(fFitter->Eval());
	294	delete [] index;
	295	delete [] dist;
	296
	297	// retrive fitter results
	298	TMatrixD cov(fLambda, fLambda);
	299	TVectorD par(fLambda);
	300	fFitter->GetCovarianceMatrix(cov);
	301	fFitter->GetParameters(par);
	302	Double_t chi2 = fFitter->GetChisquare()/(npoints - 4 - fLambda);
	303
	304	// store results
	305	node->Store(&par, HasStore()?&cov:NULL);
	306
	307	// Build df/dpi\|x values
	308	Double_t *fdfdp = &fBuffer[fLambda];
	309	ipar = 0;
	310	fdfdp[ipar++] = 1.;
	311	for(int idim=0; idim<fNSize; idim++){
	312	fdfdp[ipar++] = point[idim];
	313	for(int jdim=idim; jdim<fNSize; jdim++) fdfdp[ipar++] = point[idim]*point[jdim];
	314	}
	315
	316	// calculate estimation
	317	result =0.; error = 0.;
	318	for(int i=0; i<fLambda; i++){
	319	result += fdfdp[i]*par(i);
	320	for(int j=0; j<fLambda; j++) error += fdfdp[i]fdfdp[j]cov(i,j);
	321	}
	322	error = TMath::Sqrt(error);
	323	return chi2;
	324	}
	325
	326	//_________________________________________________________________
	327	void TKDInterpolatorBase::DrawProjection(UInt_t ax1, UInt_t ax2)
	328	{
	329	// Draw nodes structure projected on plane "ax1:ax2". The parameter
	330	// "depth" specifies the bucket size per node. If depth == -1 draw only
	331	// terminal nodes and evaluation points (default -1 i.e. bucket size per node equal bucket size specified by the user)
	332	//
	333
	334	Float_t ax1min, ax1max, ax2min, ax2max;
	335	GetRange(ax1, ax1min, ax1max);
	336	GetRange(ax2, ax2min, ax2max);
	337	TH2 *h2 = NULL;
	338	if(!(h2 = (TH2S*)gROOT->FindObject("hKDnodes"))){
	339	h2 = new TH2S("hKDnodes", "", 100, ax1min, ax1max, 100, ax2min, ax2max);
	340	}
	341	h2->GetXaxis()->SetRangeUser(ax1min, ax1max);
	342	h2->GetXaxis()->SetTitle(Form("x_{%d}", ax1));
	343	h2->GetYaxis()->SetRangeUser(ax2min, ax2max);
	344	h2->GetYaxis()->SetTitle(Form("x_{%d}", ax2));
	345	h2->Draw();
	346
	347
	348	if(!fNodesDraw) fNodesDraw = new TKDNodeInfo::TKDNodeDraw[GetNTNodes()];
	349	TKDNodeInfo::TKDNodeDraw *box = NULL;
	350	for(Int_t in=GetNTNodes(); in--; ){
	351	box = &(fNodesDraw[in]);
	352	box->SetNode((TKDNodeInfo)((fNodes)[in]), fNSize, ax1, ax2);
	353	box->Draw();
	354	}
	355
	356	return;
	357	}
	358
	359	//_________________________________________________________________
	360	void TKDInterpolatorBase::SetAlpha(Float_t a)
	361	{
	362	if(a<0.5){
	363	Warning("TKDInterpolatorBase::SetAlpha()", "The scale parameter has to be larger than 0.5");
	364	fAlpha = 0.5;
	365	return;
	366	}
	367	// check value
	368	if(Int_t((a+1.)*fLambda) > GetNTNodes()){
	369	fAlpha = TMath::Max(0.5, Float_t(GetNTNodes())/fLambda-1.);
	370	Warning("TKDInterpolatorBase::SetAlpha()", Form("Interpolation neighborhood exceeds number of evaluation points. Downscale alpha to %f", fAlpha));
	371	printf("n[%d] nodes[%d]\n", Int_t((fAlpha+1.)*fLambda), GetNTNodes());
	372	return;
	373	}
	374	fAlpha = a;
	375	return;
	376	}
	377