libs/math/example/jacobi_zeta_example.cpp
// Copyright Paul A. Bristow, 2019 // Use, modification and distribution are subject to the // Boost Software License, Version 1.0. // (See accompanying file LICENSE_1_0.txt // or copy at http://www.boost.org/LICENSE_1_0.txt) /*! \title Simple example of computation of the Jacobi Zeta function using Boost.Math, and also using corresponding WolframAlpha commands. */ #ifdef BOOST_NO_CXX11_NUMERIC_LIMITS # error "This example requires a C++ compiler that supports C++11 numeric_limits. Try C++11 or later." #endif #include <boost/math/special_functions/jacobi_zeta.hpp> // For jacobi_zeta function. #include <boost/multiprecision/cpp_bin_float.hpp> // For cpp_bin_float_50. #include <iostream> #include <limits> #include <iostream> #include <exception> int main() { try { std::cout.precision(std::numeric_limits<double>::max_digits10); // Show all potentially significant digits. std::cout.setf(std::ios_base::showpoint); // Include any significant trailing zeros. using boost::math::jacobi_zeta; // jacobi_zeta(T1 k, T2 phi) |k| <=1, k = sqrt(m) using boost::multiprecision::cpp_bin_float_50; // Wolfram Mathworld function JacobiZeta[phi, m] where m = k^2 // JacobiZeta[phi,m] gives the Jacobi zeta function Z(phi | m) // If phi = 2, and elliptic modulus k = 0.9 so m = 0.9 * 0.9 = 0.81 // https://reference.wolfram.com/language/ref/JacobiZeta.html // Function information. // A simple computation using phi = 2. and m = 0.9 * 0.9 // JacobiZeta[2, 0.9 * 0.9] // https://www.wolframalpha.com/input/?i=JacobiZeta%5B2,+0.9+*+0.9%5D // -0.248584... // To get the expected 17 decimal digits precision for a 64-bit double type, // we need to ask thus: // N[JacobiZeta[2, 0.9 * 0.9],17] // https://www.wolframalpha.com/input/?i=N%5BJacobiZeta%5B2,+0.9+*+0.9%5D,17%5D double k = 0.9; double m = k * k; double phi = 2.; std::cout << "m = k^2 = " << m << std::endl; // m = k^2 = 0.81000000000000005 std::cout << "jacobi_zeta(" << k << ", " << phi << " ) = " << jacobi_zeta(k, phi) << std::endl; // jacobi_zeta(0.90000000000000002, 2.0000000000000000 ) = // -0.24858442708494899 Boost.Math // -0.24858442708494893 Wolfram // that agree within the expected precision of 17 decimal digits for 64-bit type double. // We can also easily get a higher precision too: // For example, to get 50 decimal digit precision using WolframAlpha: // N[JacobiZeta[2, 0.9 * 0.9],50] // https://www.wolframalpha.com/input/?i=N%5BJacobiZeta%5B2,+0.9+*+0.9%5D,50%5D // -0.24858442708494893408462856109734087389683955309853 // Using Boost.Multiprecision we can do them same almost as easily. // To check that we are not losing precision, we show all the significant digits of the arguments ad result: std::cout.precision(std::numeric_limits<cpp_bin_float_50>::digits10); // Show all significant digits. // We can force the computation to use 50 decimal digit precision thus: cpp_bin_float_50 k50("0.9"); cpp_bin_float_50 phi50("2."); std::cout << "jacobi_zeta(" << k50 << ", " << phi50 << " ) = " << jacobi_zeta(k50, phi50) << std::endl; // jacobi_zeta(0.90000000000000000000000000000000000000000000000000, // 2.0000000000000000000000000000000000000000000000000 ) // = -0.24858442708494893408462856109734087389683955309853 // and a comparison with Wolfram shows agreement to the expected precision. // -0.24858442708494893408462856109734087389683955309853 Boost.Math // -0.24858442708494893408462856109734087389683955309853 Wolfram // Taking care not to fall into the awaiting pit, we ensure that ALL arguments passed are of the // appropriate 50-digit precision and do NOT suffer from precision reduction to that of type double, // We do NOT write: std::cout << "jacobi_zeta<cpp_bin_float_50>(0.9, 2.) = " << jacobi_zeta<cpp_bin_float_50>(0.9, 2) << std::endl; // jacobi_zeta(0.90000000000000000000000000000000000000000000000000, // 2.0000000000000000000000000000000000000000000000000 ) // = -0.24858442708494895921459900494815797085727097762164 << Wrong at about 17th digit! // -0.24858442708494893408462856109734087389683955309853 Wolfram } catch (std::exception const& ex) { // Lacking try&catch blocks, the program will abort after any throw, whereas the // message below from the thrown exception will give some helpful clues as to the cause of the problem. std::cout << "\n""Message from thrown exception was:\n " << ex.what() << std::endl; // An example of message: // std::cout << " = " << jacobi_zeta(2, 0.5) << std::endl; // Message from thrown exception was: // Error in function boost::math::ellint_k<long double>(long double) : Got k = 2, function requires |k| <= 1 // Shows that first parameter is k and is out of range, as the definition in docs jacobi_zeta(T1 k, T2 phi); } } // int main()