mirror of
https://github.com/gwm17/catima.git
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231 lines
7.4 KiB
C++
231 lines
7.4 KiB
C++
/*
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* Author: Andrej Prochazka
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* Copyright(C) 2017
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU Affero General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU Affero General Public License for more details.
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* You should have received a copy of the GNU Affero General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#ifndef STORAGE
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#define STORAGE
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#include <vector>
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#include <array>
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#include <iterator>
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#include <cmath>
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//#include <unordered_set>
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#include "catima/build_config.h"
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#include "catima/constants.h"
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#include "catima/structures.h"
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#include "catima/config.h"
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#include "catima/spline.h"
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namespace catima{
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/**
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* Class to store energy points, log spaced from logmin to logmax.
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*/
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template<int N>
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struct EnergyTable{
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EnergyTable(double logmin, double logmax):values(),step(0.0),num(N){
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step = (logmax-logmin)/(N - 1.0);
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for(auto i=0;i<N;i++){
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values[i]=exp(M_LN10*(logmin + ((double)i)*step));
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}
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}
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double operator()(int i)const{return values[i];}
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double operator[](int i)const{return values[i];}
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static constexpr int size() {return N;};
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double values[N];
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double step;
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double* begin(){return values;}
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double* end(){return &values[num];}
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int index(double v)const noexcept{
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double lxval = (log(v/values[0])/M_LN10);
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if(v<values[0] || step==0.0)return -1;
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if(v>=values[N-1]-numeric_epsilon)return N-1;
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int i = static_cast<int> (std::floor(lxval/step));
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if(v >= values[i+1]-numeric_epsilon)i++; // this is correction for floating point precision
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return i;
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};
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std::size_t num;
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};
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extern EnergyTable<max_datapoints> energy_table;
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template<int N>
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int EnergyTable_index(const EnergyTable<N> &table, double val){
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if(val<table.values[0] || val>table.values[table.num-1])return -1;
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double lxval = (log(val/table.values[0])/M_LN10);
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int i = static_cast<int>( std::floor(lxval/table.step));
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if(val >= table.values[i+1]-numeric_epsilon)i++; // this is correction for floating point precision
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return i;
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}
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template<int N>
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double EnergyTable_interpolate(const EnergyTable<N> &table, double xval, double *y){
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double r;
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if(xval<table.values[0] || xval>table.values[table.num-1])return 0.0;
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if(xval==table.values[table.num-1])return y[table.num-1];
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int i = EnergyTable_index(table, xval);
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double linstep = table.values[i+1] - table.values[i];
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if(linstep == 0.0)return table.values[i];
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double x = 1.0 - ((xval - table.values[i])/linstep);
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r = (x*y[i]) + ((1-x)*y[i+1]);
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return r;
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}
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//////////////////////////////////////////////////////////////////////////////////////
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#ifdef GSL_INTERPOLATION
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/// Interpolation class, to store interpolated values
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class InterpolatorGSL{
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public:
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InterpolatorGSL(){};
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InterpolatorGSL(const EnergyTable<max_datapoints>& x, const std::vector<double>& y, interpolation_t type=cspline);
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~InterpolatorGSL();
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double operator()(double x)const{return eval(x);};
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double eval(double x) const;
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double derivative(double x) const;
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double get_min()const{return min;};
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double get_max()const{return max;};
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private:
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double min=0;
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double max=0;
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gsl_interp_accel *acc;
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gsl_spline *spline;
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};
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#endif
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class InterpolatorCSpline{
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public:
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using xtype = EnergyTable<max_datapoints>;
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InterpolatorCSpline()=default;
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InterpolatorCSpline(const xtype &table, const std::vector<double> &y):
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min(table.values[0]), max(table.values[max_datapoints-1]), ss(table,y){}
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double operator()(double x)const{return eval(x);}
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double eval(double x)const{return ss.evaluate(x);}
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double derivative(double x)const{return ss.deriv(x);}
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double get_min()const{return min;}
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double get_max()const{return max;}
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private:
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double min=0;
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double max=0;
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cspline_special<xtype> ss;
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};
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#ifdef GSL_INTERPOLATION
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using Interpolator = InterpolatorGSL;
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#else
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using Interpolator = InterpolatorCSpline;
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#endif
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#ifdef STORE_SPLINES
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using spline_type = const Interpolator&;
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#else
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using spline_type = Interpolator;
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#endif
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// return vector with lineary spaced elements from a to b, num is number of elements
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/**
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* @brief structure to store calculated data points and optionally also splines
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*/
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class DataPoint{
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public:
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Projectile p;
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Material m;
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Config config;
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std::vector<double> range;
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std::vector<double> range_straggling;
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std::vector<double> angular_variance;
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#ifdef STORE_SPLINES
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Interpolator range_spline;
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Interpolator range_straggling_spline;
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Interpolator angular_variance_spline;
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#endif
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DataPoint()=default;
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DataPoint(const Projectile _p, const Material _m,const Config &_c=default_config):p(_p),m(_m),config(_c){}
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DataPoint(const DataPoint&)=delete;
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DataPoint(DataPoint&&)=default;
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DataPoint& operator=(const DataPoint&)=default;
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DataPoint& operator=(DataPoint&&)=default;
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friend bool operator==(const DataPoint &a, const DataPoint &b);
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};
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#ifdef STORE_SPLINES
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const Interpolator& get_range_spline(const DataPoint &data);
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const Interpolator& get_range_straggling_spline(const DataPoint &data);
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const Interpolator& get_angular_variance_spline(const DataPoint &data);
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#else
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Interpolator get_range_spline(const DataPoint &data);
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Interpolator get_range_straggling_spline(const DataPoint &data);
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Interpolator get_angular_variance_spline(const DataPoint &data);
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#endif
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/**
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* @brief The Data class to store DataPoints
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*/
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class Data{
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public:
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Data();
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~Data();
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/**
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* @brief Add new DataPoint
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* @param p - Projectile
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* @param t - Material
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* @param c - Config
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*/
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void Add(const Projectile &p, const Material &t, const Config &c=default_config);
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int GetN() const {return storage.size();};
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void Reset(){storage.clear();storage.resize(max_storage_data);index=storage.begin();};
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/**
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* @brief Get DataPoint reference for projectile-target-config combination
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* @param p - Projectile
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* @param t - Material
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* @param c - Config
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* @return reference to DataPoint
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*/
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DataPoint& Get(const Projectile &p, const Material &t, const Config &c=default_config);
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DataPoint& Get(unsigned int i){return storage[i];};
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int get_index() {return std::distance(storage.begin(),index);}
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private:
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std::vector<DataPoint> storage;
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std::vector<DataPoint>::iterator index;
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};
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extern Data _storage;
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/**
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* @brief get_data - Get DataPoint from the global storage class
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* @param p - Projectile
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* @param t - Material
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* @param c - Config
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* @return const reference to DataPoint
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*/
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inline const DataPoint& get_data(const Projectile &p, const Material &t, const Config &c=default_config){
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return _storage.Get(p, t, c);
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}
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bool operator==(const DataPoint &a, const DataPoint &b);
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}
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#endif
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