10

What would be the best practice in C++, to define two separate constructors, one having input in degrees whilst the other in radians? The problem I'm having doing it the straight forward way is that the signature of both methods look the same to the compiler, even though the parameter names identify which is which, and the compiler flags a re-declaration error. Is this possible to do without introducing another field?

I can do it using a single constructor by adding an additional bool parameter that would allow selecting which units are being passed, and using an if in the body.

10
  • Constructor for what? Is your class representing an Angle? You can make static functions: fromRadians and fromDegrees – byxor Jul 20 '17 at 16:47
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    Instead of using a flag, that is going to be opaque, either write two factory functions or, preferably, create types that correspond to the different units of measure and overload on them. – Aluan Haddad Jul 20 '17 at 16:48
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    You would be surprised, but there are more than 2 representations of angle, so I would use enum not bool. And even if you need only 2 enum is more readable. – Slava Jul 20 '17 at 16:50
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    @Slava any flag will be a source of bugs in this case. It is almost a guarantee. – Aluan Haddad Jul 20 '17 at 16:51
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    @AluanHaddad using bool would be much worse than enum. – Slava Jul 20 '17 at 16:55
15

Use the named constructor idiom. Make your constructor private, and pick whichever you prefer for the argument type, degrees or radians. Then make appropriately named static member functions which do the necessary conversion.

class Angle {
public:
    static Angle radians(double r) { return Angle(r); }
    static Angle degrees(double d) { return Angle(d / 180.0 * PI); }
private:
    double angle_in_radians;
    Angle(double r) :angle_in_radians(r) {}
};
8
  • Most probably radians would be preferable as almost all standard functions work with them. – Slava Jul 20 '17 at 16:53
  • @Slava: There are advantages to degrees though. Namely, that you can store a right angle, as well as many other commonly encountered angles(45, 30, 60, 180, 270), with exact precision. – Benjamin Lindley Jul 20 '17 at 17:16
  • This is a very solid answer. The only thing I dislike is that the factories are static class members. It would be more idiomatic to put them in a namespace as free functions. Think std::make_shared, or std::for_each. Another nitpick is that you are returning the result of another constructor instead of using C++11 delegating constructors. – Aluan Haddad Jul 20 '17 at 17:16
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    @AluanHaddad: More idiomatic to whom? The named constructor idiom has been on Marshall Cline's C++FAQ for over 20 years, and now it's on the official isocpp website. Doesn't get any more idiomatic than that, when it comes to C++. And how can I use a delegating constructor in a static member function(or a free function, if I go with your suggestion)? – Benjamin Lindley Jul 20 '17 at 17:23
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    @AluanHaddad: Bjarne Stroustrup doesn't determine what is idiomatic C++ (at least not solely). C++ users do. That said, this is the front page of the FAQ I linked to: isocpp.org/wiki/faq -- You may notice a familiar name near the top. – Benjamin Lindley Jul 20 '17 at 17:32
6

What would be the best practice in C++, to define two separate constructors, one having input in degrees whilst the other in radians?

The best practice would be to have only a single constructor that clearly takes only one of them (most probably radians, since all the trigonometrical functions work with radians).

You should have additional functions to convert the values. One way is to use user defined literals1.

These are meant to give plain values a context with a particular unit to use.


I would go the following way:

constexpr long double operator"" _deg ( long double deg )
{
    return deg2rad(deg);
}

long double deg2rad(long double deg) {
    return deg*3.141592/180;
}

long double rad2deg(long double rad) {
    return (rad/3.141592)*180;
}

class Angle {
public:

    /**
     * Default constructor.
     */
    Angle() : radians() {}
    /**
     * Takes the initial angle value as radians.
     */
    Angle(long double rad) : radians(rad) {}

    // Convenience setters and getters
    void rad(long double value) {
        radians = value;
    }
    long double rad() const {
        return radians;
    }
    void deg(long double value) {
        radians = deg2rad(value);
    }
    long double deg() const {
        return rad2deg(radians);
    }
private:
    long double radians; // Only use radians internally
};

int main() {
    Angle ang1(180_deg); // Initialize using the constexpr conversion
    long double deg = 0;
    std::cout << "Enter an angle value in degrees: " << std::flush;
    std::cin >> deg;
    Angle ang2(deg2rad(deg));

}

1 The examples from the documentation even have one for converting degrees to radians.

0
3

I suggest an approach such as

const auto PI = 22 / 7.0;

const struct Degrees {
    explicit constexpr Degrees(double value): value{value} {}
    const double value;
};
const struct Radians {
    explicit constexpr Radians(double value): value{value} {}
    const double value;
};

const struct Angle {
    constexpr Angle(Radians r) : radians{r} {}
    constexpr Angle(Degrees d) : Angle{Radians{180.0 * (d.value / PI)}} {}
    const Radians radians;
};

decltype(auto) operator <<(std::ostream& out, const Degrees& d) {
    return out << d.value << " degrees";
}
decltype(auto) operator <<(std::ostream& out, const Radians& r) {
    return out << r.value << " radians";
}
decltype(auto) operator <<(std::ostream& out, const Angle& a) {
    return out << "angle: " << a.radians;
}

int main() {
    auto d = Degrees{1};
    auto a1 = Angle{Radians{1.65}};
    auto a2 = Angle{Degrees{240}};
    std::cout << a1 << '\n' << "Press any key to continue...\n";
    std::cin.get();
}

Notice how we have made the constructors for Radians and Degrees explicit. This prevents them from being called implicitely, requiring that the user declare their intent.

Now in this case, implicit construction such as

auto a = Angle{1.65}; // won't compile due to ambiguity

would cause an ambiguity error, but that may not remain true over many iterations of API releases.

For example if we removed or changed the visibility of one of the Angle constructors, the code above would compile without error.

The explicit constructors for Degrees and Radians prevents this hazard and make the code clearer.

We can add user defined literals as syntactic sugar on top of these types to enable a more terse notation.

For example:

constexpr auto operator ""_deg(long double d) { return Degrees(d); }

and

constexpr auto operator ""_rad(long double r) { return Radians(r); }

enable

auto a = Angle{240.0_deg};

and

auto a = Angle{1.65_rad};

respectively

This works because of the enhanced constexpr facilities in recent versions of the language. Since we marked our constructors as compile time-evaluatable, they can be used as the types of literals. Note my literals are potentially truncating from long double to double and I have yet to learn why declaring them as long double is required at least in MSVC 19.11.25505.

Update:

After reading through the other answers, which I thoroughly enjoyed (thanks all), I realized that much more compile time evaluation was in order so I added a slightly revised implementation incorporating some of what I learned. It is also more lightweight than my previous version and doesn't use accessors.

The implementation above is the revised version.

0
1

Varying Benjamin's approach:

class Angle
{
public:
    class Radian; // both with constructor accepting the value
    class Degree; // and a member to store it - ommitting internals

    Angle(Radian const& r);
    Angle(Degree const& d);
};

Angle(Angle::Degree(180));
Angle(Angle::Radian(4.7));
1

One option is to use disambiguation tags.

constexpr struct radians_t {
    constexpr explicit radians_t() = default;
} radians;

constexpr struct degrees_t {
    constexpr explicit degrees_t() = default;
} degrees;

Then define your constructors:

foo(double a, radians_t);
foo(double a, degrees_t);

And invoke like so:

foo(90.0, degrees);
foo(3.14, radians);

While superficially similar to the "named factory" solution, disambiguation tags are compatible with things like perfect forwarding and placement new. For example:

auto p1 = new (buffer) foo(90.0, degrees);
auto p2 = std::make_unique<foo>(3.14, radians);
7
  • Doesn't this lead to the same ultimate problem as the Boolean flag though? I mean sure the names are great, but their is nothing that ties tag to the value, so it seems like an easy API call incorrectly. – Aluan Haddad Jul 20 '17 at 17:39
  • @AluanHaddad It's better than the boolean flag because a) it's more explicit and b) the unit selection is made at compile time. Sure, I agree that having radians and degrees encapsulate the value is maybe preferable, but that answer has already been given, so I was just providing an alternative. – Joseph Thomson Jul 20 '17 at 17:45
  • Fair enough, but I think that factories and types kind of cover good solutions. I appreciate the use of constexpr, its always interesting to see new applications of it, but I'd be hard pressed to recommend this approach is all. – Aluan Haddad Jul 20 '17 at 17:47
  • @AluanHaddad I much prefer it to the named factory approach, because it allows you to call the constructor directly, which gives more flexibility (e.g. use with placement new/emplace/in_place). I would say it's second in my book to having actual types, but it's nice and quick and easy when you don't necessarily want to spend time implementing those classes. – Joseph Thomson Jul 20 '17 at 18:37
  • That an excellent point! I had not considered that. However, given how lightweight the types are in my answer, 2 lines of implementation per unit, how would you compare the unit types approach to the disambiguation tags approach. I'm honestly looking for feedback. – Aluan Haddad Jul 20 '17 at 18:43
1

I'll say at the beginning that this is a heavier approach, but you can make a rigorous separation of degrees and radians throughout your application by using opaque typedefs. This would prevent accidental mixing of values with different units -- they become compile-time errors rather than run-time errors. I have an opaque typedef library that makes it convenient to create numeric opaque typedefs and to express the operations allowed on them.

You could make separate degrees and radians types, with degrees convertible to radians, like this:

#include "opaque/numeric_typedef.hpp"

constexpr auto PI = 22 / 7.0;

struct degrees : opaque::numeric_typedef<double, degrees> {
  using base = opaque::numeric_typedef<double, degrees>;
  using base::base;
};

struct radians : opaque::numeric_typedef<double, radians> {
  using base = opaque::numeric_typedef<double, radians>;
  using base::base;
  constexpr radians(degrees d) : base(d.value/180.0 * PI) { }
};

class Angle {
public:
  Angle(radians r) : angle_in_radians(r) { }
private:
  radians angle_in_radians;
};

int main() {
  Angle a(degrees(90.0));
  Angle b(radians(1.23));
  Angle c(5.0); // compile error
}

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