79

What is the purpose of anonymous enum declarations such as:

enum { color = 1 };

Why not just declare int color = 1?

8
  • 1
    You could but that saves up memory.
    – atoMerz
    Aug 22 '11 at 11:49
  • 1
    in which way can save menory?
    – user707549
    Aug 22 '11 at 11:52
  • 1
    @ratzip: See my answer below.
    – sharptooth
    Aug 22 '11 at 11:54
  • 3
    @ratzip: The compiler may burn it into the CPU intructions, like foo = color; --> mov 1, foo Aug 22 '11 at 11:58
  • 7
    The compiler just replaces color with 1. Just like the number 42 doesn't take up memory in your program enums don't either. BTW damn you for making me misspell colour :)
    – Motti
    Aug 22 '11 at 11:59
97

That's a so-called enum trick for declaring a compile-time integer constant. It's advantage is it guarantees that no variable is instantiated and therefore there's no runtime overhead. Most compilers introduce no overhead with integer constants anyway.

3
  • +1: This is the correct answer. There is no valid reason for using an enum in place of a const int apart from this. Aug 22 '11 at 11:59
  • 3
    +1 should be accepted answer. Great, short and sweet explanation.
    – user195488
    Aug 22 '11 at 12:56
  • I too like this answer. Rummaging through the kernel sources of Linux I've now become aware of this trick. One possible reason for using enum over the const int alternative is that using enum allows for an organized method of grouping like-purposed names. Aug 18 '15 at 19:52
69

Enums don't take up any space and are immutable.

If you used const int color = 1; then you would solve the mutability issue but if someone took the address of color (const int* p = &color;) then space for it would have to be allocated. This may not be a big deal but unless you explicitly want people to be able to take the address of color you might as well prevent it.

Also when declaring a constant field in a class then it will have to be static const (not true for modern C++) and not all compilers support inline initialization of static const members.


Disclaimer: This answer should not be taken as advice to use enum for all numeric constants. You should do what you (or your co-workers) think is more readable. The answer just lists some reasons one might prefer to use an enum.

12
  • 4
    const int is immutable, and may not take up any space, depending on what the compiler chooses to do. Aug 22 '11 at 11:52
  • @Oli Charlesworth How can constants not take up space? What if I'm initializing constant at runtime?
    – atoMerz
    Aug 22 '11 at 11:53
  • 6
    @AtoMerZ: That's why I said "it depends". Also, that's not really a fair comparison; you can't change an enum at runtime! Aug 22 '11 at 11:54
  • 1
    I'm just saying constants don't do the same thing. constants have different purpose.
    – atoMerz
    Aug 22 '11 at 11:57
  • @AtoMerZ: if you initialize constants at runtime, then the compiler cannot optimize it out, obviously. Aug 22 '11 at 12:05
7

If this is old code, then enum might have been used for the "enum hack".

You can learn more about the "enum hack", for example, in this link: enum hack

1
  • 4
    Upvoted, but I recommend you describe the enum hack in your answer as well in case that link ever goes dead in the next 20 years. Oct 25 '19 at 21:36
5

One use of this is when you're doing template metaprogramming, because enum objects are not lvalues, while static const members are. It also used to be a common workaround for compilers that didn't let you initialize static integral constants in the class definition. This is explained in another question.

1
  • 1
    I believe the use in metaprogramming is gone, since C++11 added constexpr.
    – Shoe
    Apr 8 '14 at 22:40
4
(1) int color = 1;

color is changeable (accidently).

(2) enum { color = 1 };

color cannot be changed.

The other option for enum is,

const int color = 1;  // 'color' is unmutable

Both enum and const int offer exactly same concept; it's a matter of choice. With regards to popular belief that enums save space, IMO there is no memory constraint related to that, compiler are smart enough to optimize const int when needed.

[Note: If someone tries to use const_cast<> on a const int; it will result in undefined behavior (which is bad). However, the same is not possible for enum. So my personal favorite is enum]

8
  • 6
    But in general, the const int should be preferred, because the semantics more closely match the intent (it is not an enumeration!). Aug 22 '11 at 11:51
  • I think that in const int color = 1;, color could still be changed if you really wanted to, with const_cast; enum, however, can't be changed. Aug 22 '11 at 11:52
  • 5
    @Eran: No. If it is declared const, you can't const_cast the constness away: that is undefined behaviour. Aug 22 '11 at 11:54
  • 1
    @Oli, well, I will prefer enum over const int; IMO they are more organized and not likely to get victimized by const_cast and result in UB.
    – iammilind
    Aug 22 '11 at 11:54
  • 2
    @iammilind: "Much more organized"? YMMV, but my approach is to ensure my code's semantics matches my intent as closely as possible. If you're accidentally casting away constness, then you have bigger problems! Aug 22 '11 at 11:56
1

When you use
enum {color = 1}
you're not using any memory it's like
#define color 1

If you declare a variable
int color=1 Then you're taking up memory for a value that's not to be changed.

8
  • 2
    You're not taking up any memory unless the compiler decides to allocate memory for it. Aug 22 '11 at 11:58
  • By "definition" constants are variables and take up space, I'm not talking about compiler specific optimizations.
    – atoMerz
    Aug 22 '11 at 12:00
  • 2
    "taking up space" is irrelevant unless you're talking about the compiler output. And if you're worried about taking up space, then you are worrying about optimizations. No sane compiler would allocate space for a variable that is not written to. Aug 22 '11 at 12:01
  • const int x=1; const int* y=&x; cout << y;. Nothing is written into x after declaration. You might wanna see the result of this.
    – atoMerz
    Aug 22 '11 at 12:19
  • 2
    Ok, you've found another case where the compiler can't avoid allocating memory. But that doesn't detract from my main point. Aug 22 '11 at 12:36
1

Answer

Readability and performance.
Details are describbed as notes to examples below.

Use cases

Personal example

In Unreal Engine 4 (C++ game engine), I have following property (engine exposed member variable):

/// Floor Slope.

UPROPERTY
(
    Category = "Movement",
    VisibleInstanceOnly,

    BlueprintGetter = "BP_GetFloorSlope",
    BlueprintReadOnly,

    meta =
    (
        ConsoleVariable = "Movement.FloorSlope",
        DisplayName     = "Floor Slope",
        ExposeOnSpawn   = true,
        NoAutoLoad
    )
)

float FloorSlope = -1.f;

This is a value of floor slope player is standing on (value ∈ [0; 90)°), if any.
Because of engine limitations, it cannot be neither std::optional nor TOptional.
I've came up with a solution to add another self explainable variable bIsOnFloor.

bool  bIsOnFloor = false;

My C++ only internal setter for FloorSlope takes the following form:

void UMovement::SetFloorSlope(const float& FloorSlope) noexcept
    contract [[expects audit: FloorSlope >= 0._deg && FloorSlope < 90._deg]]
{
    this->bIsOnFloor = true;
    this->FloorSlope = FloorSlope;

    AUI::UI->Debug->FloorSlope = FString::Printf(L"Floor Slope: %2.0f", FloorSlope);
};

Adding special case where FloorSlope parameter would take argument of -1.f would be hard to guess and not user friendly. Instead, I'd rather create False enum field:

enum { False };

This way, I can simply overload SetFloorSlope function that takes intuitive False instead of -1.f.

void UMovement::SetFloorSlope([[maybe_unused]] const decltype(False)&) noexcept
{
    this->bIsOnFloor = false;
    this->FloorSlope = -1.f;

    AUI::UI->Debug->FloorSlope = L"Floor Slope:  —";
};


When a player character hits a floor upon applying gravity to it on tick, I simply call:

SetFloorSlope(FloorSlope);

… where FloorSlope is a float value ∈ [0; 90)°. Otherwise (if it does not hits a floor), I call:

SetFloorSlope(False);

This form (as opposed to passing -1.f) is much more readable, and self explanatory.

Engine example

Another example may be to prevent or force initialization. Mentioned above Unreal Engine 4 commonly uses FHitResult struct containing information about one hit of a trace, such as point of impact and surface normal at that point.

This complex struct calls Init method by default, setting some values to certain member variables. This can be forced or prevented (public docs: FHitResult #constructor):

FHitResult()
{
    Init();
}

explicit FHitResult(float InTime)
{
    Init();
    Time = InTime;
}

explicit FHitResult(EForceInit InInit)
{
    Init();
}

explicit FHitResult(ENoInit NoInit)
{
}

Epic Games defines such enums similiar, but adds redundant enum names:

enum EForceInit 
{
    ForceInit,
    ForceInitToZero
};
enum ENoInit {NoInit};

Passing NoInit to the constructor of FHitResult prevents initialization, what can lead to performance gain by not initializing values that will be initialized elsewhere.

Community example

FHitResult(NoInit) usage in DamirH's post on Comprehensive GameplayAbilities Analysis Series:

//A struct for temporary holding of actors (and transforms) of actors that we hit
//that don't have an ASC. Used for environment impact GameplayCues.
struct FNonAbilityTarget
{
    FGameplayTagContainer CueContainer;
    TWeakObjectPtr<AActor> TargetActor;
    FHitResult TargetHitResult;
    bool bHasHitResult;

public:
    FNonAbilityTarget()
        : CueContainer(FGameplayTagContainer())
        , TargetActor(nullptr)
        , TargetHitResult(FHitResult(ENoInit::NoInit))
        , bHasHitResult(false)
    {
    }

// (…)
0

I dont see it mentioned, another use is to scope your constants. I currently work on code that was written using Visual Studio 2005, and it is now ported to android - g++. In VS2005 you could have code like this enum MyOpts { OPT1 = 1 }; and use it as MyOpts::OPT1 - and compiler did not complain about it, even though it is not valid. g++ reports such code as error, so one solution is to use anonymous enum as follows: struct MyOpts { enum {OPT1 =1}; };, and now both compilers are happy.

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