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193 lines
6.5 KiB
C++
193 lines
6.5 KiB
C++
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// Copyright Paul Bristow 2013.
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// Copyright John Maddock 2010.
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// Use, modification and distribution are subject to the
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// Boost Software License, Version 1.0.
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// (See accompanying file LICENSE_1_0.txt
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// or copy at http://www.boost.org/LICENSE_1_0.txt)
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/*! \brief Examples of using the enhanced math constants.
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\details This allows for access to constants via functions like @c pi(),
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and also via namespaces, @c using @c namespace boost::math::double_constants;
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called simply @c pi.
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*/
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#include <boost/math/constants/constants.hpp>
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#include <iostream>
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using std::cout;
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using std::endl;
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#include <limits>
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using std::numeric_limits;
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/*! \brief Examples of a template function using constants.
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\details This example shows using of constants from function calls like @c pi(),
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rather than the 'cute' plain @c pi use in non-template applications.
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\tparam Real radius parameter that can be a built-in like float, double,
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or a user-defined type like multiprecision.
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\returns Area = pi * radius ^ 2
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*/
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//[math_constants_eg1
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template<class Real>
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Real area(Real r)
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{
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using namespace boost::math::constants;
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return pi<Real>() * r * r;
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}
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//] [/math_constants_eg1]
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int main()
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{
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{ // Boost.Math constants using function calls like pi().
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// using namespace boost::math::constants;
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using boost::math::constants::pi;
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using boost::math::constants::one_div_two_pi;
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#ifdef BOOST_NO_CXX11_NUMERIC_LIMITS
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std::size_t max_digits10 = 2 + std::numeric_limits<double>::digits * 3010/10000;
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#else
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std::size_t max_digits10 = std::numeric_limits<double>::max_digits10;
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#endif
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std::cout.precision(max_digits10);
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cout << "double pi = boost::math::double_constants::pi = " << pi<double>() << endl;
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// double pi = boost::math::double_constants::pi = 3.1415926535897931
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double r = 1.234567890123456789;
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double d = pi<double>() * r * r;
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cout << "d = " << d << ", r = " << r << endl;
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float rf = 0.987654321987654321f;
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float pif = boost::math::constants::pi<float>();
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cout << "pidf = boost::math::constants::pi() = " << pif << endl;
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// pidf = boost::math::float_constants::pi = 3.1415927410125732
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//float df = pi * rf * rf; // conversion from 'const double' to 'float', possible loss of data.
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float df = pif * rf * rf;
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cout << "df = " << df << ", rf = " << rf << endl;
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cout << "one_div_two_pi " << one_div_two_pi<double>() << endl;
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using boost::math::constants::one_div_two_pi;
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cout << "one_div_root_two_pi " << one_div_two_pi<double>() << endl;
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}
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{ // Boost math new constants using namespace selected values, like pi.
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//using namespace boost::math::float_constants;
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using namespace boost::math::double_constants;
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double my2pi = two_pi; // Uses boost::math::double_constants::two_pi;
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cout << "double my2pi = " << my2pi << endl;
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using boost::math::float_constants::e;
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float my_e = e;
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cout << "float my_e " << my_e << endl;
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double my_pi = boost::math::double_constants::pi;
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cout << "double my_pi = boost::math::double_constants::pi = " << my_pi << endl;
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// If you try to use two namespaces, this may, of course, create ambiguity:
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// it is not too difficult to do this inadvertently.
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using namespace boost::math::float_constants;
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//cout << pi << endl; // error C2872: 'pi' : ambiguous symbol.
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}
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{
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//[math_constants_ambiguity
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// If you use more than one namespace, this will, of course, create ambiguity:
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using namespace boost::math::double_constants;
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using namespace boost::math::constants;
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//double my_pi = pi(); // error C2872: 'pi' : ambiguous symbol
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//double my_pi2 = pi; // Context does not allow for disambiguation of overloaded function
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// It is also possible to create ambiguity inadvertently,
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// perhaps in other peoples code,
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// by making the scope of a namespace declaration wider than necessary,
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// therefore is it prudent to avoid this risk by localising the scope of such definitions.
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//] [/math_constants_ambiguity]
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}
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{ // You can, of course, use both methods of access if both are fully qualified, for examples:
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//cout.precision(std::numeric_limits<double>::max_digits10);// Ideally.
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cout.precision(2 + std::numeric_limits<double>::digits * 3010/10000); // If no max_digits10.
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double my_pi1 = boost::math::constants::pi<double>();
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double my_pid = boost::math::double_constants::pi;
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cout << "boost::math::constants::pi<double>() = " << my_pi1 << endl
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<< "boost::math::double_constants::pi = " << my_pid << endl;
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// cout.precision(std::numeric_limits<float>::max_digits10); // Ideally.
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cout.precision(2 + std::numeric_limits<double>::digits * 3010/10000); // If no max_digits10.
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float my_pif = boost::math::float_constants::pi;
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cout << "boost::math::float_constants::pi = " << my_pif << endl;
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}
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{ // Use with templates
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// \warning it is important to be very careful with the type provided as parameter.
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// For example, naively providing an @b integer instead of a floating-point type can be disastrous.
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// cout << "Area = " << area(2) << endl; // warning : 'return' : conversion from 'double' to 'int', possible loss of data
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// Failure to heed this warning can lead to very wrong answers!
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// Area = 12 !! = 3 * 2 * 2
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//[math_constants_template_integer_type
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//cout << "Area = " << area(2) << endl; // Area = 12!
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cout << "Area = " << area(2.) << endl; // Area = 12.566371
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// You can also avoid this by being explicit about the type of @c area.
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cout << "Area = " << area<double>(2) << endl;
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//] [/math_constants_template_integer_type]
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}
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/*
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{
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using boost::math::constants::pi;
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//double my_pi3 = pi<double>(); // OK
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//double my_pi4 = pi<>(); cannot find template type.
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//double my_pi4 = pi(); // Can't find a function.
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}
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*/
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} // int main()
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/*[constants_eq1_output
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Output:
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double pi = boost::math::double_constants::pi = 3.1415926535897931
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d = 4.7882831840285398, r = 1.2345678901234567
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pidf = boost::math::constants::pi() = 3.1415927410125732
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df = 3.0645015239715576, rf = 0.98765432834625244
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one_div_two_pi 0.15915494309189535
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one_div_root_two_pi 0.15915494309189535
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double my2pi = 6.2831853071795862
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float my_e 2.7182817459106445
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double my_pi = boost::math::double_constants::pi = 3.1415926535897931
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boost::math::constants::pi<double>() = 3.1415926535897931
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boost::math::double_constants::pi = 3.1415926535897931
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boost::math::float_constants::pi = 3.1415927410125732
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Area = 12.566370614359172
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Area = 12.566370614359172
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] [/constants_eq1_output]
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*/
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