doc/v616/Numerical2PGradientCalculator_8cxx_source.html

// @(#)root/minuit2:$Id$

// Authors: M. Winkler, F. James, L. Moneta, A. Zsenei   2003-2005


/**********************************************************************

 *                                                                    *

 * Copyright (c) 2005 LCG ROOT Math team,  CERN/PH-SFT                *

 *                                                                    *

 **********************************************************************/


#include "Minuit2/Numerical2PGradientCalculator.h"

#include "Minuit2/InitialGradientCalculator.h"

#include "Minuit2/MnFcn.h"

#include "Minuit2/MnUserTransformation.h"

#include "Minuit2/MnMachinePrecision.h"

#include "Minuit2/MinimumParameters.h"

#include "Minuit2/FunctionGradient.h"

#include "Minuit2/MnStrategy.h"


//#define DEBUG

#if defined(DEBUG) || defined(WARNINGMSG)

#include "Minuit2/MnPrint.h"

#ifdef _OPENMP

#include <omp.h>

#include <iomanip>

#ifdef DEBUG

#define DEBUG_MP

#endif

#endif

#endif


#include <math.h>


#include "Minuit2/MPIProcess.h"


namespace ROOT {


   namespace Minuit2 {


FunctionGradient Numerical2PGradientCalculator::operator()(const MinimumParameters& par) const {

   // calculate gradient using Initial gradient calculator and from MinimumParameters object


   InitialGradientCalculator gc(fFcn, fTransformation, fStrategy);

   FunctionGradient gra = gc(par);


   return (*this)(par, gra);

}


// comment it, because it was added

FunctionGradient Numerical2PGradientCalculator::operator()(const std::vector<double>& params) const {

   // calculate gradient from an std;:vector of paramteters


   int npar = params.size();


   MnAlgebraicVector par(npar);

   for (int i = 0; i < npar; ++i) {

      par(i) = params[i];

   }


   double fval = Fcn()(par);


   MinimumParameters minpars = MinimumParameters(par, fval);


   return (*this)(minpars);


}


FunctionGradient Numerical2PGradientCalculator::operator()(const MinimumParameters& par, const FunctionGradient& Gradient) const {

   // calculate numerical gradient from MinimumParameters object

   // the algorithm takes correctly care when the gradient is approximatly zero


   //    std::cout<<"########### Numerical2PDerivative"<<std::endl;

   //    std::cout<<"initial grd: "<<Gradient.Grad()<<std::endl;

   //    std::cout<<"position: "<<par.Vec()<<std::endl;


   assert(par.IsValid());


   double fcnmin = par.Fval();

   //   std::cout<<"fval: "<<fcnmin<<std::endl;


   double eps2 = Precision().Eps2();

   double eps = Precision().Eps();


   double dfmin = 8.*eps2*(fabs(fcnmin)+Fcn().Up());

   double vrysml = 8.*eps*eps;

   //   double vrysml = std::max(1.e-4, eps2);

   //    std::cout<<"dfmin= "<<dfmin<<std::endl;

   //    std::cout<<"vrysml= "<<vrysml<<std::endl;

   //    std::cout << " ncycle " << Ncycle() << std::endl;


   unsigned int n = (par.Vec()).size();

   unsigned int ncycle = Ncycle();

   //   MnAlgebraicVector vgrd(n), vgrd2(n), vgstp(n);

   MnAlgebraicVector grd = Gradient.Grad();

   MnAlgebraicVector g2 = Gradient.G2();

   MnAlgebraicVector gstep = Gradient.Gstep();


#ifndef _OPENMP

   MPIProcess mpiproc(n,0);

#endif


#ifdef DEBUG

   std::cout << "Calculating Gradient at x =   " << par.Vec() << std::endl;

   int pr = std::cout.precision(13);

   std::cout << "fcn(x) = " << fcnmin << std::endl;

   std::cout.precision(pr);

#endif


#ifndef _OPENMP

   // for serial execution this can be outside the loop

   MnAlgebraicVector x = par.Vec();


   unsigned int startElementIndex = mpiproc.StartElementIndex();

   unsigned int endElementIndex = mpiproc.EndElementIndex();


   for(unsigned int i = startElementIndex; i < endElementIndex; i++) {


#else


 // parallelize this loop using OpenMP

//#define N_PARALLEL_PAR 5

#pragma omp parallel

#pragma omp for

//#pragma omp for schedule (static, N_PARALLEL_PAR)


   for(int i = 0; i < int(n); i++) {


#endif


#ifdef DEBUG_MP

      int ith = omp_get_thread_num();

      //std::cout << "Thread number " << ith << "  " << i << std::endl;

#endif


#ifdef _OPENMP

       // create in loop since each thread will use its own copy

      MnAlgebraicVector x = par.Vec();

#endif


      double xtf = x(i);

      double epspri = eps2 + fabs(grd(i)*eps2);

      double stepb4 = 0.;

      for(unsigned int j = 0; j < ncycle; j++)  {

         double optstp = sqrt(dfmin/(fabs(g2(i))+epspri));

         double step = std::max(optstp, fabs(0.1*gstep(i)));

         //       std::cout<<"step: "<<step;

         if(Trafo().Parameter(Trafo().ExtOfInt(i)).HasLimits()) {

            if(step > 0.5) step = 0.5;

         }

         double stpmax = 10.*fabs(gstep(i));

         if(step > stpmax) step = stpmax;

         //       std::cout<<" "<<step;

         double stpmin = std::max(vrysml, 8.*fabs(eps2*x(i)));

         if(step < stpmin) step = stpmin;

         //       std::cout<<" "<<step<<std::endl;

         //       std::cout<<"step: "<<step<<std::endl;

         if(fabs((step-stepb4)/step) < StepTolerance()) {

            //    std::cout<<"(step-stepb4)/step"<<std::endl;

            //    std::cout<<"j= "<<j<<std::endl;

            //    std::cout<<"step= "<<step<<std::endl;

            break;

         }

         gstep(i) = step;

         stepb4 = step;

         //       MnAlgebraicVector pstep(n);

         //       pstep(i) = step;

         //       double fs1 = Fcn()(pstate + pstep);

         //       double fs2 = Fcn()(pstate - pstep);


         x(i) = xtf + step;

         double fs1 = Fcn()(x);

         x(i) = xtf - step;

         double fs2 = Fcn()(x);

         x(i) = xtf;


         double grdb4 = grd(i);

         grd(i) = 0.5*(fs1 - fs2)/step;

         g2(i) = (fs1 + fs2 - 2.*fcnmin)/step/step;


#ifdef DEBUG

         pr = std::cout.precision(13);

         std::cout << "cycle " << j << " x " << x(i) << " step " << step << " f1 " << fs1 << " f2 " << fs2

                   << " grd " << grd(i) << " g2 " << g2(i) << std::endl;

         std::cout.precision(pr);

#endif


         if(fabs(grdb4-grd(i))/(fabs(grd(i))+dfmin/step) < GradTolerance())  {

            //    std::cout<<"j= "<<j<<std::endl;

            //    std::cout<<"step= "<<step<<std::endl;

            //    std::cout<<"fs1, fs2: "<<fs1<<" "<<fs2<<std::endl;

            //    std::cout<<"fs1-fs2: "<<fs1-fs2<<std::endl;

            break;

         }

      }


#ifdef DEBUG_MP

#pragma omp critical

      {

         std::cout << "Gradient for thread " << ith << "  " << i << "  " << std::setprecision(15)  << grd(i) << "  " << g2(i) << std::endl;

      }

#endif


      //     vgrd(i) = grd;

      //     vgrd2(i) = g2;

      //     vgstp(i) = gstep;


#ifdef DEBUG

      pr = std::cout.precision(13);

      int iext = Trafo().ExtOfInt(i);

      std::cout << "Parameter " << Trafo().Name(iext) << " Gradient =   " << grd(i) << " g2 = " << g2(i) << " step " << gstep(i) << std::endl;

      std::cout.precision(pr);

#endif

   }


#ifndef _OPENMP

   mpiproc.SyncVector(grd);

   mpiproc.SyncVector(g2);

   mpiproc.SyncVector(gstep);

#endif


#ifdef DEBUG

   std::cout << "Calculated Gradient at x =   " << par.Vec() << std::endl;

   std::cout << "fcn(x) = " << fcnmin << std::endl;

   std::cout << "Computed gradient in N2PGC " << grd << std::endl;

#endif


   return FunctionGradient(grd, g2, gstep);

}


const MnMachinePrecision& Numerical2PGradientCalculator::Precision() const {

   // return global precision (set in transformation)

   return fTransformation.Precision();

}


unsigned int Numerical2PGradientCalculator::Ncycle() const {

   // return number of cycles for gradient calculation (set in strategy object)

   return Strategy().GradientNCycles();

}


double Numerical2PGradientCalculator::StepTolerance() const {

   // return gradient step tolerance (set in strategy object)

   return Strategy().GradientStepTolerance();

}


double Numerical2PGradientCalculator::GradTolerance() const {

   // return gradient tolerance (set in strategy object)

   return Strategy().GradientTolerance();

}


   }  // namespace Minuit2


}  // namespace ROOT

FunctionGradient.h

InitialGradientCalculator.h

MPIProcess.h

MinimumParameters.h

MnFcn.h

MnMachinePrecision.h

MnPrint.h

MnStrategy.h

MnUserTransformation.h

Numerical2PGradientCalculator.h

sqrt
double sqrt(double)

ROOT::Minuit2::FunctionGradient
Definition: FunctionGradient.h:21

ROOT::Minuit2::FunctionGradient::Gstep
const MnAlgebraicVector & Gstep() const
Definition: FunctionGradient.h:52

ROOT::Minuit2::FunctionGradient::Grad
const MnAlgebraicVector & Grad() const
Definition: FunctionGradient.h:46

ROOT::Minuit2::FunctionGradient::G2
const MnAlgebraicVector & G2() const
Definition: FunctionGradient.h:51

ROOT::Minuit2::InitialGradientCalculator
Class to calculate an initial estimate of the gradient.
Definition: InitialGradientCalculator.h:28

ROOT::Minuit2::LAVector
Definition: LAVector.h:33

ROOT::Minuit2::MPIProcess
Definition: MPIProcess.h:46

ROOT::Minuit2::MPIProcess::SyncVector
bool SyncVector(ROOT::Minuit2::MnAlgebraicVector &mnvector)
Definition: MPIProcess.cxx:160

ROOT::Minuit2::MPIProcess::StartElementIndex
unsigned int StartElementIndex() const
Definition: MPIProcess.h:57

ROOT::Minuit2::MPIProcess::EndElementIndex
unsigned int EndElementIndex() const
Definition: MPIProcess.h:61

ROOT::Minuit2::MinimumParameters
Definition: MinimumParameters.h:21

ROOT::Minuit2::MinimumParameters::Fval
double Fval() const
Definition: MinimumParameters.h:47

ROOT::Minuit2::MinimumParameters::IsValid
bool IsValid() const
Definition: MinimumParameters.h:48

ROOT::Minuit2::MinimumParameters::Vec
const MnAlgebraicVector & Vec() const
Definition: MinimumParameters.h:45

ROOT::Minuit2::MnFcn::Up
double Up() const
Definition: MnFcn.cxx:35

ROOT::Minuit2::MnMachinePrecision
determines the relative floating point arithmetic precision.
Definition: MnMachinePrecision.h:27

ROOT::Minuit2::MnMachinePrecision::Eps
double Eps() const
eps returns the smallest possible number so that 1.+eps > 1.
Definition: MnMachinePrecision.h:44

ROOT::Minuit2::MnMachinePrecision::Eps2
double Eps2() const
eps2 returns 2*sqrt(eps)
Definition: MnMachinePrecision.h:47

ROOT::Minuit2::MnStrategy::GradientStepTolerance
double GradientStepTolerance() const
Definition: MnStrategy.h:42

ROOT::Minuit2::MnStrategy::GradientTolerance
double GradientTolerance() const
Definition: MnStrategy.h:43

ROOT::Minuit2::MnStrategy::GradientNCycles
unsigned int GradientNCycles() const
Definition: MnStrategy.h:41

ROOT::Minuit2::MnUserTransformation::ExtOfInt
unsigned int ExtOfInt(unsigned int internal) const
Definition: MnUserTransformation.h:103

ROOT::Minuit2::MnUserTransformation::Name
const char * Name(unsigned int) const
Definition: MnUserTransformation.cxx:450

ROOT::Minuit2::MnUserTransformation::Precision
const MnMachinePrecision & Precision() const
forwarded interface
Definition: MnUserTransformation.h:122

ROOT::Minuit2::Numerical2PGradientCalculator::Trafo
const MnUserTransformation & Trafo() const
Definition: Numerical2PGradientCalculator.h:58

ROOT::Minuit2::Numerical2PGradientCalculator::fFcn
const MnFcn & fFcn
Definition: Numerical2PGradientCalculator.h:68

ROOT::Minuit2::Numerical2PGradientCalculator::Strategy
const MnStrategy & Strategy() const
Definition: Numerical2PGradientCalculator.h:60

ROOT::Minuit2::Numerical2PGradientCalculator::operator()
virtual FunctionGradient operator()(const MinimumParameters &) const
Definition: Numerical2PGradientCalculator.cxx:41

ROOT::Minuit2::Numerical2PGradientCalculator::Precision
const MnMachinePrecision & Precision() const
Definition: Numerical2PGradientCalculator.cxx:237

ROOT::Minuit2::Numerical2PGradientCalculator::GradTolerance
double GradTolerance() const
Definition: Numerical2PGradientCalculator.cxx:252

ROOT::Minuit2::Numerical2PGradientCalculator::fTransformation
const MnUserTransformation & fTransformation
Definition: Numerical2PGradientCalculator.h:69

ROOT::Minuit2::Numerical2PGradientCalculator::Ncycle
unsigned int Ncycle() const
Definition: Numerical2PGradientCalculator.cxx:242

ROOT::Minuit2::Numerical2PGradientCalculator::Fcn
const MnFcn & Fcn() const
Definition: Numerical2PGradientCalculator.h:57

ROOT::Minuit2::Numerical2PGradientCalculator::fStrategy
const MnStrategy & fStrategy
Definition: Numerical2PGradientCalculator.h:70

ROOT::Minuit2::Numerical2PGradientCalculator::StepTolerance
double StepTolerance() const
Definition: Numerical2PGradientCalculator.cxx:247

x
Double_t x[n]
Definition: legend1.C:17

n
const Int_t n
Definition: legend1.C:16

ROOT::Math::fabs
VecExpr< UnaryOp< Fabs< T >, VecExpr< A, T, D >, T >, T, D > fabs(const VecExpr< A, T, D > &rhs)
Definition: UnaryOperators.h:131

ROOT
Namespace for new ROOT classes and functions.
Definition: StringConv.hxx:21