73

Is there a way in C++ to extend/"inherit" enums?

I.E:

enum Enum {A,B,C};
enum EnumEx : public Enum {D,E,F};

or at least define a conversion between them?

2

10 Answers 10

65

No, there is not.

enum are really the poor thing in C++, and that's unfortunate of course.

Even the class enum introduced in C++0x does not address this extensibility issue (though they do some things for type safety at least).

The only advantage of enum is that they do not exist: they offer some type safety while not imposing any runtime overhead as they are substituted by the compiler directly.

If you want such a beast, you'll have to work yourself:

  • create a class MyEnum, that contains an int (basically)
  • create named constructors for each of the interesting values

you may now extend your class (adding named constructors) at will...

That's a workaround though, I have never found a satistifying way of dealing with an enumeration...

2
  • Alas, I agree. So many time I have wanted a type safe way of passing flags etc. but enums are really just ints. – Tim Allman Nov 26 '09 at 17:46
  • Enums are unfortunately not the only poor thing in C++ ... – Johannes Overmann Aug 4 '20 at 10:29
10

I've solved in this way:

typedef enum
{
    #include "NetProtocols.def"
} eNetProtocols, eNP;

Of course, if you add a new net protocol in the NetProtocols.def file, you have to recompile, but at least it's expandable.

1
  • Yeah, if you want the enum definition to be in a library, you would not be able to do that... – Alexis Wilke Jul 26 '19 at 3:39
6

If you were able to create a subclass of an enum it'd have to work the other way around.

The set of instances in a sub-class is a subset of the instances in the super-class. Think about the standard "Shape" example. The Shape class represents the set of all Shapes. The Circle class, its subclass, represents the subset of Shapes that are Circles.

So to be consistent, a subclass of an enum would have to contain a subset of the elements in the enum it inherits from.

(And no, C++ doesn't support this.)

7
  • 6
    That's a very specific interpretation of inheritance, that doesn't necessarily apply to all uses of inheritance. I don't think it really explains why a compiler couldn't support enum EnumEx : public Enum {D,E,F}; such that an EnumEx could be passed to a function expecting an Enum. – jon-hanson Nov 26 '09 at 17:38
  • 1
    @jon: because it would break the Liskov substitution principle: D would "be an" Enum (because it inherits from it), but it wouldn't have any of the valid values of an Enum. Contradiction. enums are designed to be "enumerated types" - the whole point is that you define the type by defining all valid objects of that type (in the case of C/C++, actually the map from listed values to all valid types is a bit weird, and involves the type used to represent the enum). This may be a very specific interpretation of inheritance, but it's a good one, and AFAIK it informs the design of C++. – Steve Jessop Nov 26 '09 at 20:20
  • 1
    As a particular example where it would break, suppose I define an enum A {1, 65525}; and the compiler decides to use a 16bit unsigned int to represent it. Now suppose I define enumEx : public Enum { 131071 };. There's no way this object of type EnumEx can be passed as an instance of Enum, it would in effect be sliced. Oops. This is why you need pointers in C++ to do runtime polymorphism. I guess C++ could make every enum the size of the largest possible enum. But conceptually speaking, the value 131071 should not be a valid instance of Enum. – Steve Jessop Nov 26 '09 at 20:32
  • 3
    What you actually want when you "extend an enum", probably, is to pass an Enum to a function expecting an EnumEx. As Laurence says, this is the other way around from usual inheritance, and it's not at all clear that inheritance is a good model for it. enums are bad enough as they are, without C++ muddling things further with a version of inheritance that's different from class inheritance. – Steve Jessop Nov 26 '09 at 20:35
  • 1
    This is not an explanation. In C++ it's perfectly possible to say e.g. struct S{ enum {A,B,C}; }; struct T : S {enum {D=3,E,F};};, so that now T, being a subclass of S, still contains a superset of the elements: A, B, C, D, E and F – Ruslan Dec 4 '19 at 13:24
4

A simple, but useful workaround for this c++ gap could be as follows:

#define ENUM_BASE_VALS A,B,C
enum Enum {ENUM_BASE_VALS};
enum EnumEx {ENUM_BASE_VALS, D,E,F};
4

I had this problem in some projects that ran on small hardware devices I design. There is a common project that holds a number of services. Some of these services use enums as parameters to get additional type checking and safety. I needed to be able to extend these enums in the projects that use these services.

As other people have mentioned c++ doesn't allow you to extend enums. You can however emulate enums using a namespace and a template that has all the benefits of enum class.

enum class has the following benefits:

  1. Converts to a known integer type.
  2. Is a value type
  3. Is constexpr by default and takes up no valuable RAM on small processors
  4. Is scoped and accessible by enum::value
  5. Works in case statements
  6. Provides type safety when used as a parameter and needs to be explicitly cast

Now if you define a class as an enum you can't create constexpr instances of the enum in the class declaration, because the class is not yet complete and it leads to a compile error. Also even if this worked you could not extend the value set of enums easily later in another file/sub project .

Now namespaces have no such problem but they don't provide type safety.

The answer is to first create a templated base class which allows enums of different base sizes so we don't waste what we don't use.

template <typename TYPE>
class EnumClass {
  private:
    TYPE value_;
  public:
    explicit constexpr EnumClass(TYPE value) :
        value_(value){
    }
    constexpr EnumClass() = default;
    ~EnumClass() = default;
    constexpr explicit EnumClass(const EnumClass &) = default;
    constexpr EnumClass &operator=(const EnumClass &) = default;

    constexpr operator TYPE() const {return    value_;}
    constexpr TYPE value() const {return value_;}

};

Then for each enum class we want to extend and emulate we create a namespace and a Type like this:

namespace EnumName {
   class Type :public Enum<uint8_t> {
     public:
        explicit constexpr Type(uint8_t value): Enum<uint8_t>(value){}
        constexpr Enum() = default;
   }
   constexpr auto Value1 = Type(1); 
   constexpr auto Value2 = Type(2); 
   constexpr auto Value3 = Type(3); 
}

Then later in your code if you have included the original EnumName you can do this:

   namespace EnumName {
       constexpr auto Value4 = Type(4U); 
       constexpr auto Value5 = Type(5U); 
       constexpr auto Value6 = Type(6U); 

       constexpr std::array<Type, 6U> Set = {Value1, Value2, Value3, Value4, Value5, Value6};
    }

now you can use the Enum like this:

#include <iostream>

void fn(EnumName::Type val){
    if( val != EnumName::Value1 ){
      std::cout << val;
    }
}

int main(){
  for( auto e :EnumName::Set){
    switch(e){
      case EnumName::Value1:  
        std::cout << "a";
        break;
      case EnumName::Value4:  
        std::cout << "b";
        break;
      default:
        fn(e);
    }
  }
}

So we have a case statement, enum comparisons, parameter type safety and its all extensible. Note the set is constexpr and wont end up using valuable RAM on a small micro (placement verified on Godbolt.org. :-). As a bonus we have the ability to iterate over a set of enum values.

1

http://www.codeproject.com/KB/cpp/InheritEnum.aspx goes over a method to created an expanded enum.

3
  • 2
    A very dangerous method. If two enums being put together use the same value, this silently confuses them. – dspeyer Jan 24 '13 at 18:48
  • 2
    @dspeyer it still brings an interesting idea to the whole debate. your solution is an offspring of this. – v.oddou Jun 22 '16 at 3:51
  • Answers should not be just links. (And that code has undefined behavior in its “casting”.) – Davis Herring Feb 29 '20 at 0:58
1

I do this '

'''
    enum OPC_t // frame Operation Codes
    {
      OPC_CVSND = 0 // Send CV value
    , OPC_CVREQ = 1 // Request CV (only valid for master app)
    , OPC_COMND = 2 // Command
    , OPC_HRTBT = 3 // Heart Beat
    };
    enum rxStatus_t     // this extends OPC_t
    {
      RX_CVSND = OPC_CVSND  // Send CV value
    , RX_CVREQ = OPC_CVREQ  // Request CV
    , RX_COMND = OPC_COMND  // Command
    , RX_HRTBT = OPC_HRTBT  // Heart Beat
    , RX_NONE       // No new Rx
    , RX_NEWCHIP        // new chip detected
    };
''''
0

Just an idea:

You could try to create an empty class for each constant (maybe put them all in the same file to reduce clutter), create one instance of each class and use the pointers to these instances as the "constants". That way, the compiler will understand inheritance and will perform any ChildPointer-to-ParentPointer conversion necessary when using function calls, AND you still get type-safety checks by the compiler to ensure no one passes an invalid int value to functions (which would have to be used if you use the LAST value method to "extend" the enum).

Haven't fully thought this through though so any comments on this approach are welcome.

And I'll try to post an example of what I mean as soon as I have some time.

0

Actually you can extend enums in a round about way.

The C++ standard defines the valid enum values to be all the valid values of the underlying type so the following is valid C++ (11+). Its not Undefined Behaviour, but it is very nasty - you have been warned.

#include <cstdint>

    enum Test1:unit8_t {
        Value1 =0,
        Value2 =1
    };

    constexpr auto Value3 = static_cast<Test1>(3);
    constexpr auto Value4 = static_cast<Test1>(4);
    constexpr auto Value5 = static_cast<Test1>(5);


Test1 fn(Test1 val){
  switch(val){
    case Value1:
    case Value2:
    case Value3:
    case Value4:
       return Value1;
    case Value5:
       return Value5; 
  } 
}

int main(){
  return static_cast<uint8_t>(fn(Value5));
} 

Note that most of the compilers don't consider the additional values as part of the set for generating warnings about missing enums values in switch statements.So clang and gcc will warn if Value2 is missing but will do nothing if Value4 is missing in the above switch statement.

-1

The following code works well.

enum Enum {A,B,C};
enum EnumEx {D=C+1,E,F};
2
  • 9
    Doesn't really work. A is still an Enum and not an EnumEx. I.e. EnumEx x = A; will fail to compile without a cast. – jon-hanson Nov 26 '09 at 17:24
  • 2
    Actually, I am more concerned about the implications on the type-system, rather than the indexing of the values. – cvb Nov 26 '09 at 17:25

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