我正在研究涉及许多测量的项目,我想使用增强单位来确保正确转换单位。我首先介绍了一些typedef来简化表示法:
#include <boost/units/cmath.hpp>
#include <boost/units/io.hpp>
#include <boost/units/systems/si.hpp>
#include <boost/units/systems/si/io.hpp>
#include <boost/date_time/posix_time/posix_time.hpp>
namespace Time = boost::posix_time;
typedef Time::ptime DateTime;
typedef Time::time_duration Duration;
namespace Units
{
using namespace boost::units;
namespace SI
{
using namespace boost::units::si;
}
template <class U> using Quantity = quantity<U>;
typedef Quantity<SI::length> Length;
typedef Quantity<SI::velocity> Velocity;
typedef Quantity<SI::time> Time;
}
我已经编写了一些代码来计算使用这些单位的距离和旅行时间:
// a computation of distances which yields a length
Units::Length distance = origin.distance(destination);
Units::Velocity flight_speed(100 * Units::SI::meter / Units::SI::second);
Units::Time flight_time = distance / flight_speed;
DateTime departure_time = ...
DateTime arrival_time = departure_time + flight_time; // does not work..
这导致了我的问题:是否有一些内置的方式可以在Duration(又名boost::posix_time::time_duration)和time_duration Units::Quantity<SI::time>之间进行转换(又名boost::units::quantity<boost::units::si::time> })?看起来这应该是内置的,但我没有在文档中找到任何关于它的内容。
答案 0 :(得分:1)
你必须做这项工作:
DateTime arrival_time = departure_time +
boost::posix_time::seconds(flight_time / Units::SI::second);
当然,您可以在各种帮助中隐藏转换:
static inline DateTime operator+(DateTime const &lhs, Units::Time const &rhs) {
return lhs + Time::seconds(rhs / Units::SI::second);
}
static inline DateTime operator-(DateTime const &lhs, Units::Time const &rhs) {
return lhs - Time::seconds(rhs / Units::SI::second);
}
现在你可以写
了auto arrival_time = departure_time + flight_time;
<强> Live On Coliru
#include <boost/units/cmath.hpp>
#include <boost/units/io.hpp>
#include <boost/units/systems/si.hpp>
#include <boost/units/systems/si/io.hpp>
#include <boost/date_time/posix_time/posix_time.hpp>
namespace Time = boost::posix_time;
typedef Time::ptime DateTime;
typedef Time::time_duration Duration;
namespace Units {
using namespace boost::units;
namespace SI {
using namespace boost::units::si;
}
template <class U> using Quantity = quantity<U>;
typedef Quantity<SI::length> Length;
typedef Quantity<SI::velocity> Velocity;
typedef Quantity<SI::time> Time;
} // namespace Units
#include <boost/geometry.hpp>
#include <boost/geometry/geometries/point_xy.hpp>
struct MockLocation {
boost::geometry::model::d2::point_xy<double> point;
Units::Length distance(MockLocation const& other) const {
return boost::geometry::distance(point, other.point) * 1000.0 * Units::SI::meter;
}
friend std::istream& operator>>(std::istream& is, MockLocation& ml) {
double x,y;
if (is >> x >> y)
ml.point = {x,y};
return is;
}
};
#include <iostream>
static inline DateTime operator+(DateTime const &lhs, Units::Time const &rhs) {
return lhs + Time::seconds(rhs / Units::SI::second);
}
static inline DateTime operator-(DateTime const &lhs, Units::Time const &rhs) {
return lhs - Time::seconds(rhs / Units::SI::second);
}
int main() try {
MockLocation origin, destination;
std::cin.exceptions(std::ios::failbit);
std::cout << "Enter origin x,y (km): "; std::cin >> origin;
std::cout << "Enter destination x,y (km): "; std::cin >> destination;
// a computation of distances which yields a length
Units::Length distance = origin.distance(destination);
Units::Velocity flight_speed(100 * Units::SI::meter / Units::SI::second);
Units::Time flight_time = distance / flight_speed;
DateTime departure_time = Time::second_clock::local_time();
using Period = Time::time_period;
std::cout
<< "\nDistance " << distance
<< " at " << flight_speed
<< " Schedule: " << Period(departure_time, departure_time+flight_time)
<< "\n";
} catch(std::ios::failure const& e) {
std::cerr << "Input error: " << e.what() << "\n";
}
打印
Enter origin x,y (km): Enter destination x,y (km):
Distance 721110 m at 100 m s^-1 Schedule: [2018-Feb-23 14:22:55/2018-Feb-23 16:23:05.999999]