mirror of
https://github.com/gwm17/catima.git
synced 2024-11-26 20:18:51 -05:00
316 lines
14 KiB
C++
316 lines
14 KiB
C++
#include <stdexcept>
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#include <pybind11/pybind11.h>
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#include <pybind11/operators.h>
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#include <pybind11/numpy.h>
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#include <pybind11/stl.h>
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#include "catima/catima.h"
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#include "catima/srim.h"
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#include "catima/nucdata.h"
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#include <iostream>
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#include <string>
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namespace py = pybind11;
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using namespace catima;
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void catima_info(){
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printf("CATIMA version = 1.5\n");
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printf("number of energy points = %d\n",max_datapoints);
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printf("min energy point = 10^%lf MeV/u\n",logEmin);
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printf("max energy point = 10^%lf MeV/u\n",logEmax);
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}
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std::string material_to_string(const Material &r){
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std::string s;
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auto n = r.ncomponents();
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for(int i = 0; i < n; i++){
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auto el = r.get_element(i);
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s += "#"+std::to_string(i);
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s += ": A = "+std::to_string(el.A) + ", Z = "+std::to_string(el.Z)+ ", stn = "+std::to_string(el.stn)+"\n";
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}
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return s;
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};
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py::list storage_info(){
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py::list res;
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for(int i=0; i<max_storage_data;i++){
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auto& data = _storage.Get(i);
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if(data.p.A>0 && data.p.Z && data.m.ncomponents()>0){
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py::list mat;
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py::dict d;
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py::list p;
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p.append(data.p.A);
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p.append(data.p.Z);
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d["projectile"] = p;
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d["matter"] = material_to_string(data.m);
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d["config"] = py::cast(data.config);
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res.append(d);
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}
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}
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return res;
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}
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py::list get_energy_table(){
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py::list r;
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for(auto e : energy_table){
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r.append(e);
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}
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return r;
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}
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py::list get_data(Projectile& p, const Material &m, const Config& c=default_config){
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py::list r;
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auto& data = _storage.Get(p, m, c);
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py::list ran;
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py::list rans;
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py::list av;
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for(double e:data.range){ran.append(e);}
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for(double e:data.range_straggling)rans.append(e);
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for(double e:data.angular_variance)av.append(e);
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r.append(ran);
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r.append(rans);
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r.append(av);
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return r;
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}
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Material py_make_material(py::list d, double density=0.0, double thickness=0.0, double ipot=0.0, double mass=0.0){
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Material m;
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if(density>0.0)m.density(density);
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if(ipot>0.0)m.I(ipot);
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if(mass>0.0)m.M(mass);
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if(thickness>0.0)m.thickness(thickness);
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for(int i=0;i<d.size();i++){
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py::list e(d[i]);
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if(e.size() != 3)throw std::invalid_argument("invalid Material constructor argument");
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double a = e[0].cast<double>();
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int z = e[1].cast<int>();
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double stn = e[2].cast<double>();
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m.add_element(a,z,stn);
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}
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return m;
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}
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py::dict get_result_dict(const Result& r){
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py::dict d;
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d["Ein"] = r.Ein;
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d["Eout"] = r.Eout;
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d["Eloss"] = r.Eloss;
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d["range"] = r.range;
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d["dEdxi"] = r.dEdxi;
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d["dEdxo"] = r.dEdxo;
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d["sigma_E"] = r.sigma_E;
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d["sigma_r"] = r.sigma_r;
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d["sigma_a"] = r.sigma_a;
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d["sigma_x"] = r.sigma_x;
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d["tof"] = r.tof;
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d["sp"] = r.sp;
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return d;
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}
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PYBIND11_MODULE(pycatima,m){
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py::class_<Projectile>(m,"Projectile")
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.def(py::init<>(),"constructor")
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.def(py::init<double, double, double, double>(), "constructor", py::arg("A"),py::arg("Z"),py::arg("Q")=0, py::arg("T")=0)
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.def("__call__",&Projectile::operator())
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.def("A",[](const Projectile& p){return p.A;})
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.def("Z",[](const Projectile& p){return p.Z;})
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.def("Q",[](const Projectile& p){return p.Q;})
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.def("T",[](const Projectile& p){return p.T;})
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.def("T",[](Projectile& p, double v){p.T = v;});
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//.def_readwrite("A", &Projectile::A)
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//.def_readwrite("Z", &Projectile::Z)
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//.def_readwrite("T", &Projectile::T)
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//.def_readwrite("Q", &Projectile::Q);
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py::class_<Target>(m,"Target")
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.def(py::init<>(),"constructor")
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.def_readwrite("A",&Target::A)
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.def_readwrite("Z",&Target::Z)
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.def_readwrite("stn",&Target::stn);
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py::class_<Material>(m,"Material")
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.def(py::init<>(),"constructor")
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.def(py::init<const Material&>(),"constructor")
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.def(py::init<double, int, double, double, double>(),"constructor", py::arg("A"),py::arg("Z"),py::arg("density")=0.0,py::arg("thickness")=0.0,py::arg("i_potential")=0.0)
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.def(py::init(&py_make_material),"constructor", py::arg("elements"),py::arg("density")=0.0,py::arg("thickness")=0.0,py::arg("i_potential")=0.0, py::arg("mass")=0.0)
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.def("add_element",&Material::add_element)
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.def("ncomponents",&Material::ncomponents)
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.def("density",py::overload_cast<>(&Material::density, py::const_), "get density")
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.def("density",py::overload_cast<double>(&Material::density), "set density")
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.def("molar_mass",py::overload_cast<>(&Material::M, py::const_), "get mass")
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.def("thickness",py::overload_cast<>(&Material::thickness, py::const_), "get thickness")
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.def("thickness",py::overload_cast<double>(&Material::thickness), "set thickness")
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.def("thickness_cm",py::overload_cast<double>(&Material::thickness_cm),"set thickness in cm unit")
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.def("I",py::overload_cast<>(&Material::I, py::const_), "get I")
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.def("I",py::overload_cast<double>(&Material::I), "set I")
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.def("__str__",&material_to_string);
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py::class_<Layers>(m,"Layers")
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.def(py::init<>(),"constructor")
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.def("add",py::overload_cast<Material>(&Layers::add))
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.def("add_layers",py::overload_cast<const Layers&>(&Layers::add))
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.def("num",&Layers::num)
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// .def("__getitem__",&Layers::operator[], py::is_operator())
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.def("__getitem__",[](Layers &r, int i)->Material*
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{
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if(i>=r.num()){
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throw std::invalid_argument("index out of range");}
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return &r[i];
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}, py::is_operator(),py::return_value_policy::automatic_reference)
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.def("get",&Layers::operator[])
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.def(py::self + py::self)
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.def("__add__",[](const Layers s, const Material& m){return s+m;});
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py::class_<Result>(m,"Result")
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.def(py::init<>(),"constructor")
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.def_readwrite("Ein", &Result::Ein)
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.def_readwrite("Eout", &Result::Eout)
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.def_readwrite("Eloss", &Result::Eloss)
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.def_readwrite("range", &Result::range)
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.def_readwrite("dEdxi", &Result::dEdxi)
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.def_readwrite("dEdxo", &Result::dEdxo)
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.def_readwrite("sigma_E", &Result::sigma_E)
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.def_readwrite("sigma_a", &Result::sigma_a)
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.def_readwrite("sigma_r", &Result::sigma_r)
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.def_readwrite("sigma_x", &Result::sigma_x)
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.def_readwrite("tof", &Result::tof)
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.def_readwrite("sp", &Result::sp)
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.def("get_dict",&get_result_dict);
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py::class_<MultiResult>(m,"MultiResult")
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.def(py::init<>(),"constructor")
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.def_readwrite("total_result", &MultiResult::total_result)
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.def_readwrite("results", &MultiResult::results)
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// .def_readwrite("Eout",&MultiResult::total_result.Eout)
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.def("__getitem__",[](MultiResult &r, int i){
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return py::cast(r.results[i]);
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},py::is_operator())
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.def("__getattr__",[](MultiResult &r, std::string& k){
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if(k.compare("Eout")==0){
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return py::cast(r.total_result.Eout);
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}
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else if(k.compare("sigma_a")==0){
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return py::cast(r.total_result.sigma_a);
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}
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else if(k.compare("tof")==0){
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return py::cast(r.total_result.tof);
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}
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else if(k.compare("Eloss")==0){
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return py::cast(r.total_result.Eloss);
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}
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else{
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return py::cast(NULL);
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}
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},py::is_operator())
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.def("get_dict",[](const MultiResult &r){
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py::dict d;
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py::list p;
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d["result"] = get_result_dict(r.total_result);
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for(auto& entry:r.results){
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p.append(get_result_dict(entry));
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}
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d["partial"] = p;
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return d;
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});
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py::enum_<z_eff_type>(m,"z_eff_type")
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.value("none", z_eff_type::none)
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.value("pierce_blann", z_eff_type::pierce_blann)
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.value("anthony_landorf", z_eff_type::anthony_landorf)
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.value("hubert", z_eff_type::hubert)
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.value("winger", z_eff_type::winger)
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.value("schiwietz", z_eff_type::schiwietz)
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.value("cglobal", z_eff_type::global)
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.value("atima14", z_eff_type::atima14);
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py::enum_<corrections>(m,"corrections")
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.value("no_barkas", corrections::no_barkas)
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.value("no_lindhard", corrections::no_lindhard)
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.value("no_shell_correction", corrections::no_shell_correction)
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.value("no_highenergy", corrections::no_highenergy);
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py::enum_<omega_types>(m,"omega_types")
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.value("atima", omega_types::atima)
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.value("bohr", omega_types::bohr);
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py::enum_<low_energy_types>(m,"low_energy_types")
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.value("srim_85", low_energy_types::srim_85)
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.value("srim_95", low_energy_types::srim_95);
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py::enum_<material>(m,"material")
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.value("Plastics", material::Plastics)
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.value("Air", material::Air)
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.value("CH2", material::CH2)
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.value("lH2", material::lH2)
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.value("lD2", material::lD2)
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.value("Water", material::Water)
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.value("Diamond", material::Diamond)
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.value("Glass", material::Glass)
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.value("ALMG3", material::ALMG3)
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.value("ArCO2_30", material::ArCO2_30)
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.value("CF4", material::CF4)
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.value("Isobutane", material::Isobutane)
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.value("Kapton", material::Kapton)
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.value("Mylar", material::Mylar)
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.value("NaF", material::NaF)
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.value("P10", material::P10)
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.value("Polyolefin", material::Polyolefin)
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.value("CmO2", material::CmO2)
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.value("Suprasil", material::Suprasil)
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.value("HAVAR", material::HAVAR)
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.value("Steel", material::Steel)
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.value("CO2", material::CO2);
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py::class_<Config>(m,"Config")
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.def(py::init<>(),"constructor")
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.def_readwrite("z_effective", &Config::z_effective)
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.def_readwrite("corrections", &Config::corrections)
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.def_readwrite("calculation", &Config::calculation)
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.def("get",[](const Config &r){
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py::dict d;
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d["z_effective"] = r.z_effective;
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d["corrections"] = r.corrections;
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d["calculation"] = r.calculation;
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return d;
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})
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.def("__str__",[](const Config &r){
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std::string s;
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s = "z_effective = "+std::to_string(r.z_effective);
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s += ", corrections = "+std::to_string(r.corrections);
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s += ", calculation = "+std::to_string(r.calculation);
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return s;
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});
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m.def("srim_dedx_e",&srim_dedx_e);
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m.def("sezi_dedx_e",&sezi_dedx_e, "sezi_dedx_e", py::arg("projectile"), py::arg("material"), py::arg("config")=default_config);
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m.def("calculate",py::overload_cast<Projectile, const Material&, const Config&>(&calculate),"calculate",py::arg("projectile"), py::arg("material"), py::arg("config")=default_config);
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m.def("calculate_layers",py::overload_cast<const Projectile&, const Layers&, const Config&>(&calculate),"calculate_layers",py::arg("projectile"), py::arg("material"), py::arg("config")=default_config);
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m.def("dedx_from_range",py::overload_cast<const Projectile&, const Material&, const Config&>(&dedx_from_range),"calculate",py::arg("projectile") ,py::arg("material"), py::arg("config")=default_config);
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m.def("dedx_from_range",py::overload_cast<const Projectile&, const std::vector<double>&, const Material&, const Config&>(&dedx_from_range),"calculate",py::arg("projectile"), py::arg("energy") ,py::arg("material"), py::arg("config")=default_config);
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m.def("dedx",py::overload_cast<const Projectile&, const Material&, const Config&>(&dedx), "dedx",py::arg("projectile"), py::arg("material"), py::arg("config")=default_config);
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m.def("range",py::overload_cast<const Projectile&, const Material&, const Config&>(&range), "range",py::arg("projectile"), py::arg("material"), py::arg("config")=default_config);
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m.def("energy_out",py::overload_cast<const Projectile&, const std::vector<double>&, const Material&, const Config&>(&energy_out),"energy_out",py::arg("projectile"), py::arg("energy") ,py::arg("material"), py::arg("config")=default_config);
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m.def("energy_out",py::overload_cast<const Projectile&, const Material&, const Config&>(&energy_out),"energy_out",py::arg("projectile"), py::arg("material"), py::arg("config")=default_config);
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m.def("lindhard",&bethek_lindhard);
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m.def("lindhard_X",&bethek_lindhard_X);
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m.def("get_material",py::overload_cast<int>(&get_material));
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m.def("get_data",py::overload_cast<Projectile&, const Material&, const Config&>(get_data),"list of data",py::arg("projectile"),py::arg("material"),py::arg("config")=default_config);
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m.def("w_magnification",[](Projectile& p, double energy, const Material& m, const Config& c){
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py::list l;
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auto r = w_magnification(p, energy, m, c);
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l.append(r.first);
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l.append(r.second);
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return l;
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});
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m.def("catima_info",&catima_info);
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m.def("storage_info",&storage_info);
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m.def("get_energy_table",&get_energy_table);
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m.def("energy_table",[](int i){return energy_table(i);});
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m.def("z_effective",&z_effective);
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m.attr("max_datapoints") = max_datapoints;
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m.attr("max_storage_data") = max_storage_data;
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m.attr("logEmin")=logEmin;
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m.attr("logEmax")=logEmax;
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}
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