// Class: ReadFisher // Automatically generated by MethodBase::MakeClass // /* configuration options ===================================================== #GEN -*-*-*-*-*-*-*-*-*-*-*- general info -*-*-*-*-*-*-*-*-*-*-*- Method : Fisher::Fisher TMVA Release : 4.2.1 [262657] ROOT Release : 6.22/06 [398854] Creator : glencowan Date : Wed Nov 3 00:36:24 2021 Host : Darwin bigsurx.internal.macports.net 20.1.0 Darwin Kernel Version 20.1.0: Sat Oct 31 00:07:11 PDT 2020; root:xnu-7195.50.7~2/RELEASE_X86_64 x86_64 Dir : /Users/glencowan/cowan/teach/ph4515/21/problems/ps5/tmva/train Training events: 2000 Analysis type : [Classification] #OPT -*-*-*-*-*-*-*-*-*-*-*-*- options -*-*-*-*-*-*-*-*-*-*-*-*- # Set by User: V: "False" [Verbose output (short form of "VerbosityLevel" below - overrides the latter one)] H: "True" [Print method-specific help message] Method: "Fisher" [Discrimination method] # Default: VerbosityLevel: "Default" [Verbosity level] VarTransform: "None" [List of variable transformations performed before training, e.g., "D_Background,P_Signal,G,N_AllClasses" for: "Decorrelation, PCA-transformation, Gaussianisation, Normalisation, each for the given class of events ('AllClasses' denotes all events of all classes, if no class indication is given, 'All' is assumed)"] CreateMVAPdfs: "False" [Create PDFs for classifier outputs (signal and background)] IgnoreNegWeightsInTraining: "False" [Events with negative weights are ignored in the training (but are included for testing and performance evaluation)] ## #VAR -*-*-*-*-*-*-*-*-*-*-*-* variables *-*-*-*-*-*-*-*-*-*-*-*- NVar 3 x x x x 'F' [-3.60392403603,3.5663151741] y y y y 'F' [-2.58809733391,4.20677995682] z z z z 'F' [0.000381360063329,0.998853266239] NSpec 0 ============================================================================ */ #include #include #include #include #include #ifndef IClassifierReader__def #define IClassifierReader__def class IClassifierReader { public: // constructor IClassifierReader() : fStatusIsClean( true ) {} virtual ~IClassifierReader() {} // return classifier response virtual double GetMvaValue( const std::vector& inputValues ) const = 0; // returns classifier status bool IsStatusClean() const { return fStatusIsClean; } protected: bool fStatusIsClean; }; #endif class ReadFisher : public IClassifierReader { public: // constructor ReadFisher( std::vector& theInputVars ) : IClassifierReader(), fClassName( "ReadFisher" ), fNvars( 3 ) { // the training input variables const char* inputVars[] = { "x", "y", "z" }; // sanity checks if (theInputVars.size() <= 0) { std::cout << "Problem in class \"" << fClassName << "\": empty input vector" << std::endl; fStatusIsClean = false; } if (theInputVars.size() != fNvars) { std::cout << "Problem in class \"" << fClassName << "\": mismatch in number of input values: " << theInputVars.size() << " != " << fNvars << std::endl; fStatusIsClean = false; } // validate input variables for (size_t ivar = 0; ivar < theInputVars.size(); ivar++) { if (theInputVars[ivar] != inputVars[ivar]) { std::cout << "Problem in class \"" << fClassName << "\": mismatch in input variable names" << std::endl << " for variable [" << ivar << "]: " << theInputVars[ivar].c_str() << " != " << inputVars[ivar] << std::endl; fStatusIsClean = false; } } // initialize min and max vectors (for normalisation) fVmin[0] = 0; fVmax[0] = 0; fVmin[1] = 0; fVmax[1] = 0; fVmin[2] = 0; fVmax[2] = 0; // initialize input variable types fType[0] = 'F'; fType[1] = 'F'; fType[2] = 'F'; // initialize constants Initialize(); } // destructor virtual ~ReadFisher() { Clear(); // method-specific } // the classifier response // "inputValues" is a vector of input values in the same order as the // variables given to the constructor double GetMvaValue( const std::vector& inputValues ) const override; private: // method-specific destructor void Clear(); // common member variables const char* fClassName; const size_t fNvars; size_t GetNvar() const { return fNvars; } char GetType( int ivar ) const { return fType[ivar]; } // normalisation of input variables double fVmin[3]; double fVmax[3]; double NormVariable( double x, double xmin, double xmax ) const { // normalise to output range: [-1, 1] return 2*(x - xmin)/(xmax - xmin) - 1.0; } // type of input variable: 'F' or 'I' char fType[3]; // initialize internal variables void Initialize(); double GetMvaValue__( const std::vector& inputValues ) const; // private members (method specific) double fFisher0; std::vector fFisherCoefficients; }; inline void ReadFisher::Initialize() { fFisher0 = 0.960077401312; fFisherCoefficients.push_back( -0.0237260150151 ); fFisherCoefficients.push_back( -0.444975802686 ); fFisherCoefficients.push_back( -1.06821375856 ); // sanity check if (fFisherCoefficients.size() != fNvars) { std::cout << "Problem in class \"" << fClassName << "\"::Initialize: mismatch in number of input values" << fFisherCoefficients.size() << " != " << fNvars << std::endl; fStatusIsClean = false; } } inline double ReadFisher::GetMvaValue__( const std::vector& inputValues ) const { double retval = fFisher0; for (size_t ivar = 0; ivar < fNvars; ivar++) { retval += fFisherCoefficients[ivar]*inputValues[ivar]; } return retval; } // Clean up inline void ReadFisher::Clear() { // clear coefficients fFisherCoefficients.clear(); } inline double ReadFisher::GetMvaValue( const std::vector& inputValues ) const { // classifier response value double retval = 0; // classifier response, sanity check first if (!IsStatusClean()) { std::cout << "Problem in class \"" << fClassName << "\": cannot return classifier response" << " because status is dirty" << std::endl; } else { retval = GetMvaValue__( inputValues ); } return retval; }