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- #include "gtest/gtest.h"
- #include "../src/nmie-basic.hpp"
- #include "test_spec_functions_data.hpp"
- // From W. Yang APPLIED OPTICS Vol. 42, No. 9, 20 March 2003
- // Dtest refractive index is m={1.05,1}, the size parameter is x = 80
- std::vector<int> Dtest_n({0,1,30,50,60,70,75,80,85,90,99,116,130});
- std::vector< std::complex<double>>
- Dtest_D1({
- //Orig
- // {0.11449e-15 ,-0.10000e+01 },{0.74646e-04 ,-0.10000e+01 },
- // {0.34764e-01 ,-0.99870},{0.95292e-01 ,-0.99935},
- // {0.13645,-0.10019e+01 },{0.18439,-0.10070e+01 },
- // {0.21070,-0.10107e+01 },{0.23845,-0.10154e+01 },
- // {0.26752,-0.10210e+01 },{0.29777,-0.10278e+01 },
- // {0.35481,-0.10426e+01 },{0.46923,-0.10806e+01 },
- // {0.17656,-0.13895e+01 }
- // mod (from Python mpmath)
- {0.0,-1.0}, {7.464603828e-5,-0.9999958865},
- {0.03476380918,-0.9986960672},{0.09529213152,-0.999347654},
- {0.1364513887,-1.001895883},{0.184388335,-1.006979164},
- {0.2107044267,-1.01072099},{0.2384524295,-1.015382914},
- {0.2675164524,-1.021040337},{0.2977711192,-1.027753418},
- {0.3548096904,-1.042622957},{0.4692294405,-1.080629479},
- {0.5673827836,-1.121108944},
- });
- std::vector< std::complex<double>>
- Dtest_D2({{0.64966e-69 ,-0.10000e+01 },{0.74646e-04 ,-0.10000e+01 },
- {0.34764e-01 ,-0.99870},{0.95292e-01 ,-0.99935},
- {0.13645,-0.10019e+01 },{0.17769,-0.10099e+01 },
- {0.41264e-01 ,-0.21076e+01 },{-0.20190,0.10435e+01 },
- {-0.26343,0.10223e+01 },{-0.29339,0.10291e+01 },
- {-0.34969,0.10437e+01 },{-0.46296,0.10809e+01 },
- {-0.56047,0.11206e+01 }});
- std::vector< std::complex<double>>
- Dtest_D3({{0.00000,0.10000e+01 },{-0.73809e-04 ,0.10000e+01 },
- {-0.34344e-01 ,0.99912},{-0.94022e-01 ,0.10004e+01 },
- {-0.13455,0.10032e+01 },{-0.18172,0.10084e+01 },
- {-0.20762,0.10122e+01 },{-0.23494,0.10169e+01 },
- {-0.26357,0.10225e+01 },{-0.29339,0.10291e+01 },
- {-0.34969,0.10437e+01 },{-0.46296,0.10809e+01 },
- {-0.56047,0.11206e+01 }});
- void parse_mpmath_data(const double min_abs_tol, const std::tuple< std::complex<double>, int, std::complex<double>, double, double > data,
- std::complex<double> &z, int &n, std::complex<double> &func_mp,
- double &re_abs_tol, double &im_abs_tol){
- z = std::get<0>(data);
- n = std::get<1>(data);
- func_mp = std::get<2>(data);
- re_abs_tol = ( std::get<3>(data) > min_abs_tol && std::real(func_mp) < min_abs_tol)
- ? std::get<3>(data) : min_abs_tol;
- im_abs_tol = ( std::get<4>(data) > min_abs_tol && std::imag(func_mp) < min_abs_tol)
- ? std::get<4>(data) : min_abs_tol;
- // if re(func_mp) < 0.5 then round will give 0. To avoid zero tolerance add one.
- re_abs_tol *= std::abs(std::round(std::real(func_mp))) + 1;
- im_abs_tol *= std::abs(std::round(std::imag(func_mp))) + 1;
- }
- void parse2_mpmath_data(const nmie::FloatType min_abs_tol,
- const std::tuple< nmie::FloatType, std::complex<nmie::FloatType>, int, std::complex<nmie::FloatType>, nmie::FloatType, nmie::FloatType > data,
- nmie::FloatType &x, std::complex<nmie::FloatType> &m, unsigned int &n, std::complex<nmie::FloatType> &func_mp,
- nmie::FloatType &re_abs_tol, nmie::FloatType &im_abs_tol){
- x = std::get<0>(data);
- m = std::get<1>(data);
- n = std::get<2>(data);
- func_mp = std::get<3>(data);
- re_abs_tol = ( std::get<4>(data) > min_abs_tol && std::real(func_mp) < min_abs_tol)
- ? std::get<4>(data) : min_abs_tol;
- im_abs_tol = ( std::get<5>(data) > min_abs_tol && std::imag(func_mp) < min_abs_tol)
- ? std::get<5>(data) : min_abs_tol;
- // if re(func_mp) < 0.5 then round will give 0. To avoid zero tolerance add one.
- re_abs_tol *= std::abs(std::round(std::real(func_mp))) + 1;
- im_abs_tol *= std::abs(std::round(std::imag(func_mp))) + 1;
- }
- template<class T> inline T pow2(const T value) {return value*value;}
- //TEST(an_test, DISABLED_mpmath_generated_input) {
- TEST(an_test, mpmath_generated_input) {
- double min_abs_tol = 3e-14, x;
- std::complex<double> m, an_mp;
- unsigned int n;
- double re_abs_tol, im_abs_tol;
- for (const auto &data : an_test_30digits) {
- parse2_mpmath_data(min_abs_tol, data, x, m, n, an_mp, re_abs_tol, im_abs_tol);
- auto Nstop = nmie::LeRu_cutoff(m*x)+1;
- nmie::MultiLayerMie<nmie::FloatType> ml_mie;
- ml_mie.SetLayersSize({x});
- ml_mie.SetLayersIndex({m});
- ml_mie.SetMaxTerms(Nstop);
- ml_mie.calcScattCoeffs();
- auto an = ml_mie.GetAn();
- // auto bn = ml_mie.GetBn();
- if (n > an.size()) continue;
- if (n == 0) continue;
- EXPECT_NEAR(std::real(an[n-1]), std::real(an_mp), re_abs_tol)
- << "Db at n=" << n << " Nstop="<< Nstop<<" m="<<m<<" x="<<x;
- EXPECT_NEAR(std::imag(an[n-1]), std::imag(an_mp), im_abs_tol)
- << "Db at n=" << n << " Nstop="<< Nstop<<" m="<<m<<" x="<<x;
- }
- }
- //TEST(bn_test, DISABLED_mpmath_generated_input) {
- TEST(bn_test, mpmath_generated_input) {
- double min_abs_tol = 3e-14, x;
- std::complex<double> m, bn_mp;
- unsigned int n;
- double re_abs_tol, im_abs_tol;
- for (const auto &data : bn_test_30digits) {
- parse2_mpmath_data(min_abs_tol, data, x, m, n, bn_mp, re_abs_tol, im_abs_tol);
- auto Nstop = nmie::LeRu_cutoff(m*x)+1;
- nmie::MultiLayerMie<nmie::FloatType> ml_mie;
- ml_mie.SetLayersSize({x});
- ml_mie.SetLayersIndex({m});
- ml_mie.SetMaxTerms(Nstop);
- ml_mie.calcScattCoeffs();
- // auto an = ml_mie.GetAn();
- auto bn = ml_mie.GetBn();
- if (n > bn.size()) continue;
- if (n == 0) continue;
- EXPECT_NEAR(std::real(bn[n-1]), std::real(bn_mp), re_abs_tol)
- << "Db at n=" << n << " Nstop="<< Nstop<<" m="<<m<<" x="<<x;
- EXPECT_NEAR(std::imag(bn[n-1]), std::imag(bn_mp), im_abs_tol)
- << "Db at n=" << n << " Nstop="<< Nstop<<" m="<<m<<" x="<<x;
- }
- }
- //TEST(zeta_psizeta_test, DISABLED_mpmath_generated_input) {
- TEST(zeta_psizeta_test, mpmath_generated_input) {
- double min_abs_tol = 2e-10;
- std::complex<double> z, zeta_mp;
- int n;
- double re_abs_tol, im_abs_tol;
- for (const auto &data : zeta_test_16digits) {
- parse_mpmath_data(min_abs_tol, data, z, n, zeta_mp, re_abs_tol, im_abs_tol);
- auto Nstop = nmie::LeRu_cutoff(z)+10000;
- if (n > Nstop) continue;
- std::vector<std::complex<nmie::FloatType>> D1dr(Nstop+135), D3(Nstop+135),
- PsiZeta(Nstop+135), Psi(Nstop);
- nmie::evalDownwardD1(z, D1dr);
- nmie::evalUpwardD3(z, D1dr, D3, PsiZeta);
- nmie::evalUpwardPsi(z, D1dr, Psi);
- auto a = std::real(PsiZeta[n]);
- auto b = std::imag(PsiZeta[n]);
- auto c = std::real(Psi[n]);
- auto d = std::imag(Psi[n]);
- auto c_one = std::complex<nmie::FloatType>(0, 1);
- auto zeta = (a*c + b*d)/(pow2(c) + pow2(d)) +
- c_one * ((b*c - a*d)/(pow2(c) + pow2(d)));
- // zeta = PsiZeta[n]/Psi[n];
- if (std::isnan(std::real(zeta)) || std::isnan(std::imag(zeta))) continue;
- // std::vector<std::complex<nmie::FloatType>> D1dr(Nstop+35), D3(Nstop+35), zeta(Nstop);
- // nmie::evalDownwardD1(z, D1dr);
- // nmie::evalUpwardD3(z, D1dr, D3);
- // nmie::evalUpwardZeta(z, D3, zeta);
- EXPECT_NEAR(std::real(zeta), std::real(zeta_mp), re_abs_tol)
- << "zeta at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- EXPECT_NEAR(std::imag(zeta), std::imag(zeta_mp), im_abs_tol)
- << "zeta at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- }
- }
- // // Old way to evaluate Zeta
- // TEST(zeta_test, DISABLED_mpmath_generated_input) {
- // //TEST(zeta_test, mpmath_generated_input) {
- // double min_abs_tol = 2e-5;
- // std::complex<double> z, zeta_mp;
- // int n;
- // double re_abs_tol, im_abs_tol;
- // for (const auto &data : zeta_test_16digits) {
- // parse_mpmath_data(min_abs_tol, data, z, n, zeta_mp, re_abs_tol, im_abs_tol);
- // auto Nstop = nmie::LeRu_cutoff(z)+10000;
- // if (n > Nstop) continue;
- // std::vector<std::complex<nmie::FloatType>> D1dr(Nstop), D3(Nstop),
- // PsiZeta(Nstop), zeta(Nstop);
- // nmie::evalDownwardD1(z, D1dr);
- // nmie::evalUpwardD3(z, D1dr, D3, PsiZeta);
- // nmie::evalUpwardZeta(z, D3, zeta);
- // if (std::isnan(std::real(zeta[n])) || std::isnan(std::imag(zeta[n]))) continue;
- //
- // EXPECT_NEAR(std::real(zeta[n]), std::real(zeta_mp), re_abs_tol)
- // << "zeta[n] at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- // EXPECT_NEAR(std::imag(zeta[n]), std::imag(zeta_mp), im_abs_tol)
- // << "zeta at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- // }
- //}
- //TEST(psizeta_test, DISABLED_mpmath_generated_input) {
- TEST(psizeta_test, mpmath_generated_input) {
- double min_abs_tol = 9e-11;
- std::complex<double> z, PsiZeta_mp;
- int n;
- double re_abs_tol, im_abs_tol;
- for (const auto &data : psi_mul_zeta_test_16digits) {
- parse_mpmath_data(min_abs_tol, data, z, n, PsiZeta_mp, re_abs_tol, im_abs_tol);
- auto Nstop = nmie::LeRu_cutoff(z)+10000;
- if (n > Nstop) continue;
- std::vector<std::complex<nmie::FloatType>> D1dr(Nstop), D3(Nstop), PsiZeta(Nstop);
- nmie::evalDownwardD1(z, D1dr);
- nmie::evalUpwardD3(z, D1dr, D3, PsiZeta);
- EXPECT_NEAR(std::real(PsiZeta[n]), std::real(PsiZeta_mp), re_abs_tol)
- << "PsiZeta at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- EXPECT_NEAR(std::imag(PsiZeta[n]), std::imag(PsiZeta_mp), im_abs_tol)
- << "PsiZeta at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- // std::vector<nmie::FloatType> PsiUp(Nstop);
- // nmie::evalPsi(std::real(z), PsiUp);
- // EXPECT_NEAR(((PsiUp[n])), std::real(PsiZeta_mp), re_abs_tol)
- // << "PsiZeta(up) at n=" << n << " z="<<z;
- }
- }
- TEST(psi_test, mpmath_generated_input) {
- double min_abs_tol = 1e-12;
- std::complex<double> z, Psi_mp;
- int n;
- double re_abs_tol, im_abs_tol;
- for (const auto &data : psi_test_16digits) {
- parse_mpmath_data(min_abs_tol, data, z, n, Psi_mp, re_abs_tol, im_abs_tol);
- auto Nstop = nmie::LeRu_cutoff(z)+10000;
- if (n > Nstop) continue;
- std::vector<std::complex<nmie::FloatType>> D1dr(Nstop+35), Psi(Nstop);
- nmie::evalDownwardD1(z, D1dr);
- nmie::evalUpwardPsi(z, D1dr, Psi);
- EXPECT_NEAR(std::real(Psi[n]), std::real(Psi_mp), re_abs_tol)
- << "Psi at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- EXPECT_NEAR(std::imag(Psi[n]), std::imag(Psi_mp), im_abs_tol)
- << "Psi at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- }
- }
- //TEST(D3test, DISABLED_mpmath_generated_input) {
- TEST(D3test, mpmath_generated_input) {
- double min_abs_tol = 2e-11;
- std::complex<double> z, D3_mp;
- int n;
- double re_abs_tol, im_abs_tol;
- for (const auto &data : D3_test_16digits) {
- parse_mpmath_data(min_abs_tol, data, z, n, D3_mp, re_abs_tol, im_abs_tol);
- auto Nstop = nmie::LeRu_cutoff(z)+35;
- std::vector<std::complex<nmie::FloatType>> D1dr(Nstop), D3(Nstop), PsiZeta(Nstop);
- nmie::evalDownwardD1(z, D1dr);
- nmie::evalUpwardD3(z, D1dr, D3, PsiZeta);
- EXPECT_NEAR(std::real(D3[n]), std::real(D3_mp), re_abs_tol)
- << "D3 at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- EXPECT_NEAR(std::imag(D3[n]), std::imag(D3_mp), im_abs_tol)
- << "D3 at n=" << n << " Nstop="<< Nstop<<" z="<<z;
- }
- }
- //TEST(D1test, DISABLED_mpmath_generated_input) {
- TEST(D1test, mpmath_generated_input) {
- double min_abs_tol = 2e-11, x;
- std::complex<double> m, z, D1_mp;
- unsigned int n;
- double re_abs_tol, im_abs_tol;
- for (const auto &data : D1_test_30digits) {
- parse2_mpmath_data(min_abs_tol, data, x, m, n, D1_mp, re_abs_tol, im_abs_tol);
- z = m*x;
- auto Nstop = nmie::LeRu_cutoff(z)+1;
- // auto Nstop = n;
- std::vector<std::complex<nmie::FloatType>> Db(Nstop),Dold(Nstop), r;
- int valid_digits = 10;
- int nstar = nmie::getNStar(n, z, valid_digits);
- r.resize(nstar);
- Db.resize(nstar);
- nmie::evalBackwardR(z,r);
- nmie::convertRtoD1(z, r, Db);
- if (n > Db.size()) continue;
- EXPECT_NEAR(std::real(Db[n]), std::real(D1_mp), re_abs_tol)
- << "Db at n=" << n << " Nstop="<< Nstop<<" nstar="<<nstar<< " z="<<z;
- EXPECT_NEAR(std::imag(Db[n]), std::imag(D1_mp), im_abs_tol)
- << "Db at n=" << n << " Nstop="<< Nstop<<" nstar="<<nstar<< " z="<<z;
- nmie::evalDownwardD1(z, Dold);
- if (n > Dold.size()) continue;
- EXPECT_NEAR(std::real(Dold[n]), std::real(D1_mp), re_abs_tol)
- << "Dold at n=" << n << " Nstop="<< Nstop<< " z="<<z;
- EXPECT_NEAR(std::imag(Dold[n]), std::imag(D1_mp), im_abs_tol)
- << "Dold at n=" << n << " Nstop="<< Nstop<< " z="<<z;
- }
- }
- //TEST(D1test, DISABLED_WYang_data){
- TEST(D1test, WYang_data){
- double abs_tol = 4e-10;
- int test_loss_digits = std::round(15 - std::log10(1/abs_tol));
- int Nstop = 131;
- std::vector<std::complex<nmie::FloatType>> Df(Nstop), Db(Nstop),Dold(Nstop), r;
- std::complex<nmie::FloatType> z(1.05,1);
- z = z*80.0;
- // eval D1 directly from backward recurrence
- nmie::evalDownwardD1(z, Dold);
- // eval forward recurrence
- r.resize(Nstop+1);
- nmie::evalForwardR(z, r);
- nmie::convertRtoD1(z, r, Df);
- for (unsigned int i = 0; i < Dtest_n.size(); i++) {
- unsigned int n = Dtest_n[i];
- int forward_loss_digits = nmie::evalKapteynNumberOfLostSignificantDigits(n, z);
- forward_loss_digits += 3; // Kapteyn is too optimistic
- if (test_loss_digits > forward_loss_digits ) {
- EXPECT_NEAR(std::real(Df[n]), std::real(Dtest_D1[i]),
- abs_tol) << "f at n=" << n << " lost digits = " << forward_loss_digits;
- EXPECT_NEAR(std::imag(Df[n]), std::imag(Dtest_D1[i]),
- abs_tol) << "f at n=" << n << " lost digits = " << forward_loss_digits;
- }
- // eval backward recurrence
- int valid_digits = 6;
- int nstar = nmie::getNStar(n, z, valid_digits);
- r.resize(nstar);
- Db.resize(nstar);
- nmie::evalBackwardR(z,r);
- nmie::convertRtoD1(z, r, Db);
- EXPECT_NEAR(std::real(Db[n]), std::real(Dtest_D1[i]),
- abs_tol) << "b at n=" << n;
- EXPECT_NEAR(std::imag(Db[n]), std::imag(Dtest_D1[i]),
- abs_tol) << "b at n=" << n;
- if (n < Dold.size()-15) {
- EXPECT_NEAR(std::real(Dold[n]), std::real(Dtest_D1[i]),
- abs_tol) << "old at n=" << n;
- EXPECT_NEAR(std::imag(Dold[n]), std::imag(Dtest_D1[i]),
- abs_tol) << "old at n=" << n;
- }
- }
- }
- TEST(KaptyenTest, HandlesInput) {
- // H.Du APPLIED OPTICS, Vol. 43, No. 9, 20 March 2004
- double l = nmie::evalKapteynNumberOfLostSignificantDigits(80, std::complex<double>(100,100));
- EXPECT_EQ(l, 7)<<"Should be equal";
- std::complex<double> z(10000,0);
- l = nmie::evalKapteynNumberOfLostSignificantDigits(5070, z);
- EXPECT_EQ(l, 0)<<"Should be equal";
- // find NStar such that l_nstar(z) - l_nmax(z) >= valid_digits
- int NStar = nmie::getNStar(5070, z,6);
- EXPECT_GE(NStar, 10130);
- // const double pi=3.14159265358979323846;
- // z = std::complex<double>(100,100);
- // l = nmie::evalKapteynNumberOfLostSignificantDigits(1, z);
- // EXPECT_EQ(l, 0)<<"Should be equal";
- }
- int main(int argc, char **argv) {
- testing::InitGoogleTest(&argc, argv);
- return RUN_ALL_TESTS();
- }
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