I am attempting to write a molecular dynamics program, and I thought that Boost.Units was a logical choice for the variables, and I also decided that Boost.Multiprecision offered a better option than
long double with respect to round off errors. A combination of the two seems fairly straight forward until I attempt to use a constant, then it breaks down.
#include <boost/multiprecision/gmp.hpp> #include <boost/units/io.hpp> #include <boost/units/pow.hpp> #include <boost/units/quantity.hpp> #include <boost/units/systems/si.hpp> #include <boost/units/systems/si/codata/physico-chemical_constants.hpp> namespace units = boost::units; namespace si = boost::si; namespace mp = boost::multiprecision; units::quantity<si::mass, mp::mpf_float_50> mass = 1.0 * si::kilogram; units::quantity<si::temperature, mp::mpf_float_50> temperature = 300. * si::kelvin; auto k_B = si::constants::codata::k_B; // Boltzmann constant units::quantity<si::velocity, mp::mpf_float_50> velocity = units::root<2>(temperature * k_B / mass); std::cout << velocity << std::endl;
The output will be
1 M S^-1. If I use
long double in lieu of
mp::mpf_float_50, then the result is
2.87818e-11 m s^-1. I know that the problem likes within the conversion between the constant and the other data because the constant defaults to a
double. I have thought about creating my own Boltzmann constant, but I prefer to use the predefined value if possible.
My question, therefore, is how do I go about using Boost.Multiprecision when I have predefined constants from Boost.Units? If I must concede to using
long double, then I will, but I suspect that a way exists to convert or utilize the other on the constants.
I am working with Mac OS X 10.7, Xcode 4.6.2, Clang 3.2, Boost 1.53.0 and the C++11 extensions.
I appreciate any help that can be offered.