Boost C++ Libraries

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libs/geometry/example/c01_custom_point_example.cpp

// Boost.Geometry (aka GGL, Generic Geometry Library)

// Copyright (c) 2007-2012 Barend Gehrels, Amsterdam, the Netherlands.
// Copyright (c) 2008-2012 Bruno Lalande, Paris, France.
// Copyright (c) 2009-2012 Mateusz Loskot, London, UK.

// Use, modification and distribution is 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)
//
// Custom point Example

#include <iostream>

#include <boost/geometry/algorithms/distance.hpp>
#include <boost/geometry/algorithms/make.hpp>
#include <boost/geometry/geometries/register/point.hpp>
#include <boost/geometry/strategies/strategies.hpp>
#include <boost/geometry/io/dsv/write.hpp>

// Sample point, defining three color values
struct my_color_point
{
    double red, green, blue;
};

// Sample point, having an int array defined
struct my_array_point
{
    int c[3];
};

// Sample point, having x/y
struct my_2d
{
    float x,y;
};

// Sample class, protected and construction-time-only x/y,
// Can (of course) only used in algorithms which take const& points
class my_class_ro
{
public:
    my_class_ro(double x, double y) : m_x(x), m_y(y) {}
    double x() const { return m_x; }
    double y() const { return m_y; }
private:
    double m_x, m_y;
};

// Sample class using references for read/write
class my_class_rw
{
public:
    const double& x() const { return m_x; }
    const double& y() const { return m_y; }
    double& x() { return m_x; }
    double& y() { return m_y; }
private:
    double m_x, m_y;
};

// Sample class using getters / setters
class my_class_gs
{
public:
    const double get_x() const { return m_x; }
    const double get_y() const { return m_y; }
    void set_x(double v) { m_x = v; }
    void set_y(double v) { m_y = v; }
private:
    double m_x, m_y;
};

// Sample point within a namespace
namespace my
{
    struct my_namespaced_point
    {
        double x, y;
    };
}



BOOST_GEOMETRY_REGISTER_POINT_3D(my_color_point, double, cs::cartesian, red, green, blue)
BOOST_GEOMETRY_REGISTER_POINT_3D(my_array_point, int, cs::cartesian, c[0], c[1], c[2])
BOOST_GEOMETRY_REGISTER_POINT_2D(my_2d, float, cs::cartesian, x, y)
BOOST_GEOMETRY_REGISTER_POINT_2D_CONST(my_class_ro, double, cs::cartesian, x(), y())
BOOST_GEOMETRY_REGISTER_POINT_2D(my_class_rw, double, cs::cartesian, x(), y())
BOOST_GEOMETRY_REGISTER_POINT_2D_GET_SET(my_class_gs, double, cs::cartesian, get_x, get_y, set_x, set_y)

BOOST_GEOMETRY_REGISTER_POINT_2D(my::my_namespaced_point, double, cs::cartesian, x, y)


int main()
{
    // Create 2 instances of our custom color point
    my_color_point c1 = boost::geometry::make<my_color_point>(255, 3, 233);
    my_color_point c2 = boost::geometry::make<my_color_point>(0, 50, 200);

    // The distance between them can be calculated using the cartesian method (=pythagoras)
    // provided with the library, configured by the coordinate_system type of the point
    std::cout << "color distance "
        << boost::geometry::dsv(c1) << " to "
        << boost::geometry::dsv(c2) << " is "
        << boost::geometry::distance(c1,c2) << std::endl;

    my_array_point a1 = {{0}};
    my_array_point a2 = {{0}};
    boost::geometry::assign_values(a1, 1, 2, 3);
    boost::geometry::assign_values(a2, 3, 2, 1);

    std::cout << "color distance "
        << boost::geometry::dsv(a1) << " to "
        << boost::geometry::dsv(a2) << " is "
        << boost::geometry::distance(a1,a2) << std::endl;

    my_2d p1 = {1, 5};
    my_2d p2 = {3, 4};
    std::cout << "float distance "
        << boost::geometry::dsv(p1) << " to "
        << boost::geometry::dsv(p2) << " is "
        << boost::geometry::distance(p1,p2) << std::endl;

    my_class_ro cro1(1, 2);
    my_class_ro cro2(3, 4);
    std::cout << "class ro distance "
        << boost::geometry::dsv(cro1) << " to "
        << boost::geometry::dsv(cro2) << " is "
        << boost::geometry::distance(cro1,cro2) << std::endl;

    my_class_rw crw1;
    my_class_rw crw2;
    boost::geometry::assign_values(crw1, 1, 2);
    boost::geometry::assign_values(crw2, 3, 4);
    std::cout << "class r/w distance "
        << boost::geometry::dsv(crw1) << " to "
        << boost::geometry::dsv(crw2) << " is "
        << boost::geometry::distance(crw1,crw2) << std::endl;

    my_class_gs cgs1;
    my_class_gs cgs2;
    boost::geometry::assign_values(cgs1, 1, 2);
    boost::geometry::assign_values(cgs2, 3, 4);
    std::cout << "class g/s distance "
        << boost::geometry::dsv(crw1) << " to "
        << boost::geometry::dsv(crw2) << " is "
        << boost::geometry::distance(cgs1,cgs2) << std::endl;

    my::my_namespaced_point nsp1 = boost::geometry::make<my::my_namespaced_point>(1, 2);
    my::my_namespaced_point nsp2 = boost::geometry::make<my::my_namespaced_point>(3, 4);
    std::cout << "namespaced distance "
        << boost::geometry::dsv(nsp1) << " to "
        << boost::geometry::dsv(nsp2) << " is "
        << boost::geometry::distance(nsp1,nsp2) << std::endl;


    return 0;
}