Consider that I have some 'thing' that has both enum and class behavior. As an example, consider a world which has the concept of Color, there are exactly 3: Red, Green and Blue.

Based on this color, we also have functionality, for example we could have a function which tells us whether a Color is a happy Color or not, and some other functions:

isHappy: Color -> {yes, no}
intensity: Color -> value
rotate: Color -> Color

To complete the haskel-like syntax, we could do this:

data Color = Red | Green | Blue

and implement the functions mentioned above. But that is haskell, which is not C++ and which has no notion of OO like c++ has. Continuing in C++:

The fact that we have exactly 3 colors, and no more, suggest the use of an enum; allowing us to use constants like red, blue and green anywhere in the source code. However, we cannot add methods to an enum, so isHappy intensity and rotate would be implemented as functions (and not methods).

The fact that we have these methods where the first parameter is a Color, suggest the use of a class. However, then we could instantiate as many of such classes as we'd like, especially more than 3. This means that two variables representing Red, will be allocated at different locations in memory. This is a bit strange, as Red will have very 'constant-like' behavior since it is immutable and only three different types of Color objects can be created. Moreover, we cannot use symbols like Red, Green and Blue, but would need to store them in variables. Using global variables would be very ugly imho.

We could also use inheritance, where Red, Green and Blue inherit from a Color class. This allows us to fine tune the functionality very easily, since we can implement what we want in whatever class we want. However, OO with inheritance in c++ applies slicing. For example, it would be very tricky to create a vector containing a list of (Red, Green or Blue)'s. Or to create a variable storing one of the 3 colors:

Color c1 = Red();
Color c2 = Blue();

The variables c1 and c2 will be assigned a different object, but there is no way to really distinct them. This makes implementing operator== tricky:

class Red : Color { //...
  bool operator==(Color &c) const{
     // no way to determine whether c is Red, Green or Blue.

Is there a valid pattern or solution for this situation? I think it appears a lot, hence I am very curious. C++14-only solutions are also very much appreciated!

EDIT: Many people seem to comment that the problems for the solutions that I mention are not really problems. That is a valid point. However, I'm not looking for a possible solution, I'm looking for a solution which is according to a good c++(11|14) design principles. I could also use:

#define RED 0
#define GREEN 1
#define BLUE 2

And that would work perfectly fine, however it is not a good design principle as it may collide with other functionality, using names like RED, BLUE or GREEN. This is also semantically strange, since I could say RED

Summarizing, in the answer I would like to see a solution adhering to good c++ design principles. I don't care for solutions that just work! This could be one of the three previously mentioned ways, using an enum, one class or inheritance.

EDIT2: Meanwhile I also though of a template based approach for the multiple-inheritance case. However, to be fairly honest, my knowledge of templates is not adequate yet to create something 'good'. The idea is based on functions like std::is_same and std::is_functional of the type_traits header.

#include <iostream>

class Color {};

class Red : Color {};
class Green : Color {};
class Blue : Color {};

template<class C1, class C2>
bool is_same_color();

template<class C1>
bool is_happy();

int main() {
    // your code goes here
    return 0;

It is not working, but I hope the idea get's across. Also, I realize is_same_color and is_happy should be classes with a operator() defined.

EDIT3: One could state that this is what I want:

enum Color {
  bool isHappy() { return this==GREEN || this==RED; }
  Color rotate() { return (this==RED ? GREEN (this==GREEN ? BLUE : RED)); }
  int intensity() { return (this==RED ? 11 (this==GREEN ? 12 : 4)); }

But that is of course, not valid c++.

  • 4
    I don't see any pressing reason why those can't be free functions and have to "be OO", whatever that means. – R. Martinho Fernandes Sep 5 '14 at 12:39
  • 2
    Maybe have a Color class with an embedded enumeration for the color, and have the Red, Blue etc. functions that create an appropriate object. Mix this with some operator overloads (like e.g. operator==) and it might do what you want? – Some programmer dude Sep 5 '14 at 12:45
  • 1
    "This means that two variables representing Red, will still have red1 == red2 evaluate to false." ... why exactly? – Nawaz Sep 5 '14 at 12:57
  • 3
    @Herbert Assuming you don't implement some functionality, you won't have that functionality. That is hardly a relevant design point of view. You're asking how to design stuff so that it behaves the way you want. C++ allows you to overload operator ==, therefore you should consider that doable. – Angew Sep 5 '14 at 13:03
  • 1
    Red is a constant value, not a class. Color might be a class. – CashCow Sep 5 '14 at 13:13

You may use a class and use specific instances (a la singleton) for the enum:

class Color
    bool isHappy() const { return this == &Green || this == &Red; }
    const Color* rotate() const { return (this == &Red ? &Green : (this == &Green ? &Blue : &Red)); }
    int intensity() const {return mIntensity; }

    static const Color* red() { return &Red; }
    static const Color* green() { return &Green; }
    static const Color* blue() { return &Blue; }

    // forbid to construct new instance: use only red(), green(), blue()
    explicit Color(int intensity) : mIntensity(intensity) {}
    Color(const Color&) = delete; 
    int mIntensity;

    static const Color Red;
    static const Color Green;
    static const Color Blue;

const Color Color::Red(11);
const Color Color::Green(12);
const Color Color::Blue(4);
  • Nicely done, but still the need to use pointers when put in a std container, since to the best of my knowledge they cannot contain references. – Herbert Sep 5 '14 at 14:42
  • @Herbert: You may play with std::reference_wrapper instead of pointer. – Jarod42 Sep 5 '14 at 14:51

Some other nice answers have been given, but I am afraid they don't use the C++ expression and clarity and conciseness to the full extent.

I propose the following solution:

class Color
    virtual bool is_happy() = 0;
    virtual Color* rotate() = 0;
    virtual int intensity() = 0;

    static Color* const Red;
    static Color* const Green;
    static Color* const Blue;

    Color(Color const&) = delete;


    template<bool happiness, Color* const* rotation_result, int intensity_value>
    class Color_Generator;

    template<bool happiness, Color* const* rotation_result, int intensity_value>
    friend class Color_Generator;

template<bool happiness, Color* const* rotation_result, int intensity_value>
class Color::Color_Generator : public Color
    bool is_happy()
        return happiness;

    Color* rotate()
        return *rotation_result;

    int intensity()
        return intensity_value;

    static Color_Generator<happiness, rotation_result, intensity_value> Instance;

template<bool happiness, Color* const* rotation_result, int intensity_value>
Color::Color_Generator<happiness, rotation_result, intensity_value>
Color::Color_Generator<happiness, rotation_result, intensity_value>::Instance;

Color* const Color::Red = &Color_Generator<true, &Green, 11>::Instance;
Color* const Color::Green = &Color_Generator<true, &Blue, 12>::Instance;
Color* const Color::Blue = &Color_Generator<false, &Red, 4>::Instance;

// Some usage follows

#include <iostream>

int main()
    Color* a = Color::Red;
    Color* b = Color::Green;
    Color* c = Color::Blue;

    std::cout << a->intensity() << std::endl;
    std::cout << b->is_happy() << std::endl;
    std::cout << (b->rotate() == c) << std::endl;

There are some more C++ features available to even further improve this code. For example, you might use virtual inheritance in order to split the definition of is_happy, rotate and intensity into their own 'facet' classes in the true spirit of C++.


Two givens: if you want member functions (which seems reasonable), then it must be a class; and things which differ only in attributes (like Red, Green and Blue) should not have different types.

It's not clear why you want to limit the number of colors to 3, but in the end, this comes down to ensuring that you have exactly 3 instances of your class, and no more. The simplest way of doing this is to make the constructor private, and make the instances static members:

class Color
    Color( /* whatever parameters are needed */ );
    static Color red;
    static Color green;
    static Color blue;
    //  ...

Users would then use Color::red, Color::green and Color::blue (which has the added advantage that you could do something similar with moods, and Mood::blue would not cause a naming conflict).


Update: simplified code a bit

You can implement it as base class Color which has three subclasses Red, Green and Blue, and has static constants RED, GREEN and BLUE respectively:

class Red;
class Green;
class Blue;

class Color;
typedef const Color* Color_t;

class Color {
    friend class Red;
    friend class Green;
    friend class Blue;


    static Color_t RED;
    static Color_t GREEN;
    static Color_t BLUE;

    virtual std::string name() const = 0;


    // prohibit instantiation of non-friend subclasses
    virtual ~Color() = default;

    static const Red RED_;
    static const Green GREEN_;
    static const Blue BLUE_;

class Red : public Color {
    friend class Color;
    Red() {};  // prohibit instantiation other than by Color
    std::string name() const {return "Red";}

class Green : public Color {
    friend class Color;
    Green() {};
    std::string name() const {return "Green";}

class Blue : public Color {
    friend class Color;
    Blue() {};
    std::string name() const {return "Blue";}

const Red Color::RED_;
const Green Color::GREEN_;
const Blue Color::BLUE_;

Color_t Color::RED = &RED_;
Color_t Color::GREEN = &GREEN_;
Color_t Color::BLUE = &BLUE_;

int main() {
    Color_t c = Color::GREEN;
    c = Color::BLUE;
    if (c == Color::GREEN) {
        std::cout << c-> name() << " is green" << std::endl;
    } else {
        std::cout << c-> name() << " is not green" << std::endl;

    // we can make collections of colors easily
    std::vector<Color_t> colors = { Color::RED, Color::RED, Color::GREEN, Color::BLUE, Color::GREEN };
    return 0;

Here is the demo

This is actually similar to how enums are implemented in Java.

  • I like this solution! But is it, to the best of your knowledge and judgement, the best solutions? Why is it better than the ideone.com/sQfUtf ? – Herbert Sep 5 '14 at 13:51
  • @Herbert because here you have what you wanted - a class-like behavior, demonstraned by virtual function name(). – Anton Savin Sep 5 '14 at 13:53
  • I guess the good thing is that I can append functionality in either the subclasses or the super class, avoiding switch-statements handling per-color behavior. However, how would I represent a list of red, green and blues like 'rgbrrrgbbbrrrbbrr' ? – Herbert Sep 5 '14 at 13:58
  • @Herbert exactly, you don't have to write switch statements. You can make a list as follows: std::vector<const Color*> colors = { Color::RED, Color::RED, Color::GREEN, Color::BLUE, Color::GREEN }; ` – Anton Savin Sep 5 '14 at 14:16
  • @Herbert check updated answer – Anton Savin Sep 5 '14 at 14:26

If all you want is an enum and functions that act on that enum, and a way of letting the world know that these functions and this enum belong together, then perhaps a namespace is exactly the tool for you.

namespace Color
enum EColor // or in C++11 use an enum class and set the underlying type to char or such
bool IsHappy(const EColor & color);
int Intensity(const EColor & color);
EColor Rotate(const EColor & color);

You could just as easily make this a class with member functions since every function takes an EColor to work on, but using a namespace might make it easier for you to break apart the functionality into separate modules if perhaps not every user of EColor cares about that color's happiness, or you happen to have a bunch of functions that are related to EColor but do not require a single EColor as a parameter.

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