/* * Author: Andrej Prochazka * Copyright(C) 2017 * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Affero General Public License for more details. * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . */ #ifndef STORAGE #define STORAGE #include #include //#include #include #include "catima/constants.h" #include "catima/catima.h" namespace catima{ enum interpolation_t {cspline, linear}; //inline double energy_function( int i ) { return exp(M_LN10*(logEmin + ((double)i)*(logEmax-logEmin)/(max_datapoints - 1.0))); } //enum DataType{TYPE_RANGE,TYPE_LS}; /* template struct EnergyTable{ constexpr EnergyTable(double logmin, double logmax):values(),step(0.0),num(N){ step = (logmax-logmin)/(N - 1.0); for(auto i=0;i struct EnergyTable{ EnergyTable(double logmin, double logmax):values(),step(0.0),num(N){ step = (logmax-logmin)/(N - 1.0); for(auto i=0;i energy_table; template int EnergyTable_index(const EnergyTable &table, double val){ double lxval = log(val)/M_LN10; if(valtable.values[table.num-1])return -1; int i = (int)lxval/table.step; return i; } template double EnergyTable_interpolate(const EnergyTable &table, double xval, double *y){ double r; double lxval = log(xval)/M_LN10; if(xvaltable.values[table.num-1])return 0.0; if(xval==table.values[table.num-1])return y[table.num-1]; int i = (int)(lxval/table.step); double linstep = table.values[i+1] - table.values[i]; double x = 1.0 - ((xval - table.values[i])/linstep); r = (x*y[i]) + ((1-x)*y[i+1]); return r; } /* template struct EnergyTableLinear{ constexpr EnergyTableLinear():values(),num(N){ for(auto i=0;i range; std::vector range_straggling; std::vector angular_variance; DataPoint(){}; DataPoint(const Projectile _p, const Material _m,Config _c=default_config):p(_p),m(_m),config(_c){}; ~DataPoint(); friend bool operator==(const DataPoint &a, const DataPoint &b); }; class Data{ public: Data(); ~Data(); void Add(const Projectile &p, const Material &t, Config c=default_config); int GetN() const {return storage.size();}; void Reset(){storage.clear();storage.resize(max_storage_data);index=storage.begin();}; DataPoint& Get(const Projectile &p, const Material &t, Config c=default_config); int get_index() {return std::distance(storage.begin(),index);} private: std::vector storage; std::vector::iterator index; }; /// Interpolation class, to store interpolated values class Interpolator{ public: Interpolator(const double *x, const double *y, int num,interpolation_t type=cspline); Interpolator(const std::vector& x, const std::vector& y,interpolation_t type=cspline); ~Interpolator(); double operator()(double x){return eval(x);}; double eval(double x); double derivative(double x); double get_min(){return min;}; double get_max(){return max;}; private: double min=0; double max=0; gsl_interp_accel *acc; gsl_spline *spline; }; extern Data _storage; inline DataPoint& get_data(const Projectile &p, const Material &t, Config c=default_config){ return _storage.Get(p, t, c); } bool operator==(const DataPoint &a, const DataPoint &b); } #endif