159

Treating enums as flags works nicely in C# via the [Flags] attribute, but what's the best way to do this in C++?

For example, I'd like to write:

enum AnimalFlags
{
    HasClaws = 1,
    CanFly =2,
    EatsFish = 4,
    Endangered = 8
};

seahawk.flags = CanFly | EatsFish | Endangered;

However, I get compiler errors regarding int/enum conversions. Is there a nicer way to express this than just blunt casting? Preferably, I don't want to rely on constructs from 3rd party libraries such as boost or Qt.

EDIT: As indicated in the answers, I can avoid the compiler error by declaring seahawk.flags as int. However, I'd like to have some mechanism to enforce type safety, so someone can't write seahawk.flags = HasMaximizeButton.

  • As far as I know in Visual C++ 2013 the [Flags] attribute works just fine i.e.: [Flags] enum class FlagBits{ Ready = 1, ReadMode = 2, WriteMode = 4, EOF = 8, Disabled = 16}; – rivanov Jul 21 '14 at 2:34
  • @rivanov, No it doesn't work with C++ (2015 also). Did you mean C# ? – Ajay Mar 8 '16 at 11:50
  • 3
    @rivanov, The [Flags] attribute works only with the .Net Framework in C++CLI, the native C++ does not support such attributes. – Zoltan Tirinda Apr 2 '16 at 7:11

19 Answers 19

210

The "correct" way is to define bit operators for the enum, as:

enum AnimalFlags
{
    HasClaws = 1,
    CanFly =2,
    EatsFish = 4,
    Endangered = 8
};

inline AnimalFlags operator|(AnimalFlags a, AnimalFlags b)
{return static_cast<AnimalFlags>(static_cast<int>(a) | static_cast<int>(b));}

Etc. rest of the bit operators. Modify as needed if the enum range exceeds int range.

  • 38
    ^ this. The only question is how to automate/templatize the operator definitions so you don't have to be constantly defining them every time you add a new enum. – eodabash Apr 8 '11 at 3:07
  • 8
    Also, is the cast from an arbitrary int back to the enum type valid, even if the int value does not correspond to any of the enum's identifiers? – Ingo Schalk-Schupp Dec 30 '13 at 20:47
  • 6
    This is complete nonsense. Which member of AnimalFlags is represented by the expression HasClaws | CanFly? This is not what enums are for. Use integers and constants. – Lightness Races in Orbit Mar 27 '15 at 17:49
  • 18
    @LightnessRacesinOrbit: That's not correct. The domain of an enum type is the domain of its underlying type - it's only that certain ones have been given a name. And to answer your question: The member "(HasClaws | CanFly)". – Xeo Mar 27 '15 at 18:03
  • 2
    @MarcusJ: restricting your values to powers of 2 permits you to use your enums as bit-flags. Thus if you get a 3 you know it both HasClaws( = 1) and CanFly(= 2). If instead you just assign the values 1 through 4 straight through and you get a 3, it might be a single EatsFish, or again a combination of HasClaws and CanFly. If your enumeration denotes exclusive states only then consecutive values are fine, but a combination of flags needs the values to be bit-exclusive. – Christian Severin Nov 17 '16 at 15:54
110

Note (also a bit off topic): Another way to make unique flags can be done using a bit shift. I, myself, find this easier to read.

enum Flags
{
    A = 1 << 0, // binary 0001
    B = 1 << 1, // binary 0010
    C = 1 << 2, // binary 0100
    D = 1 << 3, // binary 1000
};

It can hold values up to an int so that is, most of the time, 32 flags which is clearly reflected in the shift amount.

  • 43
    It is. I just find the 0,1,2,3 etc. easier to read. – WoutervD Apr 24 '12 at 8:20
  • 2
    Could you please delete the last comma (3,) and add a colon after } to make the code easy to copy and paste? Thanks – Katu Apr 8 '14 at 7:55
  • 2
    No mention of hexidecimal? Blasphemy! – Pharap Aug 24 '14 at 9:40
  • 1
    @Jamie, cardinals always start with 1, only ordinals may start with 0 or 1, depending on who you are talking to. – Michael Jul 7 '15 at 19:51
  • 1
    @Michael, that's true! In an enum, you usually reserve 0 for BLAH_NONE. :-) Thanks for jarring that memory! – Jamie Jul 8 '15 at 0:16
48

For lazy people like me, here is templated solution to copy&paste:

template<class T> inline T operator~ (T a) { return (T)~(int)a; }
template<class T> inline T operator| (T a, T b) { return (T)((int)a | (int)b); }
template<class T> inline T operator& (T a, T b) { return (T)((int)a & (int)b); }
template<class T> inline T operator^ (T a, T b) { return (T)((int)a ^ (int)b); }
template<class T> inline T& operator|= (T& a, T b) { return (T&)((int&)a |= (int)b); }
template<class T> inline T& operator&= (T& a, T b) { return (T&)((int&)a &= (int)b); }
template<class T> inline T& operator^= (T& a, T b) { return (T&)((int&)a ^= (int)b); }
  • 16
    +1 Laziness is one of the three great virtues of a programmer: threevirtues.com – Pharap Aug 24 '14 at 9:37
  • 7
    This is a very nice solution, just be careful that it will merrily provide bitwise operations for any type. I am using something similar, but with the addition of traits identifying the types to which I want it to apply combined with a little enable_if magic. – Rai Oct 28 '14 at 10:32
  • marking favorite because of this lazy post. :) – Izzy Feb 23 '15 at 21:19
  • 1
    @ybungalobill, but you'll still have the same problem with the operations applying to any type in the using's scope, which presumably would match the enum? I think traits are most likely necessary. – Rai Apr 10 '16 at 19:08
  • 12
    Don't use this code. It opens the door for ANY class to be operated by mistake. Also code is using old style cast which will not pass through GCC strict compilation shitalshah.com/p/…. – Shital Shah May 30 '16 at 8:54
40

What type is the seahawk.flags variable?

In standard C++, enumerations are not type-safe. They are effectively integers.

AnimalFlags should NOT be the type of your variable, your variable should be int and the error will go away.

Putting hexidecimal values like some other people suggested is not needed, it makes no difference.

The enum values ARE of type int by default. So you can surely bitwise OR combine them and put them together and store the result in an int.

The enum type is a restricted subset of int who's value is one of it's enumerated values. Hence when you make some new value outside of that range, you can't assign it without casting to a variable of your enum type.

You can also change the enum value types if you'd like, but there is no point for this question.

EDIT: The poster said they were concerned with type safety and they don't want a value that should not exist inside the int type.

But it would be type unsafe to put a value outside of AnimalFlags's range inside a variable of type AnimalFlags.

There is a safe way to check for out of range values though inside the int type...

int iFlags = HasClaws | CanFly;
//InvalidAnimalFlagMaxValue-1 gives you a value of all the bits 
// smaller than itself set to 1
//This check makes sure that no other bits are set.
assert(iFlags & ~(InvalidAnimalFlagMaxValue-1) == 0);

enum AnimalFlags {
    HasClaws = 1,
    CanFly =2,
    EatsFish = 4,
    Endangered = 8,

    // put new enum values above here
    InvalidAnimalFlagMaxValue = 16
};

The above doesn't stop you from putting an invalid flag from a different enum that has the value 1,2,4, or 8 though.

If you want absolute type safety then you could simply create an std::set and store each flag inside there. It is not space efficient but it is type safe and gives you the same ability as a bitflag int does.

C++0x note: Strongly typed enums

In C++0x you can finally have type safe enum values....

enum class AnimalFlags {
    CanFly = 2,
    HasClaws = 4
};

if(CanFly == 2) { }//Compiling error
  • 3
    The enum values aren't integers, but they very easily convert to integers. The type of HasClaws | CanFly is some integer type, but the type of HasClaws is AnimalFlags, not an integer type. – Karu Apr 23 '12 at 23:33
  • Ah, but what if we define the correct range of the enum to be not just the individual flag values but also their bitwise combinations. Then eidolon's answer is correct, and maintains that only combinations of the correct flag enum can be passed as that type. – Scott Aug 12 '13 at 2:40
  • 1
    @Scott: It's worth noting that that the C++ standard defines the valid range of values of an enum instance that way. "for an enumeration where emin is the smallest enumerator and emax is the largest, the values of the enumeration are the values in the range bmin to bmax , defined as follows: Let K be 1 for a two’s complement representation and 0 for a ones’ complement or sign-magnitude representation. bmax is the smallest value greater than or equal to max(|emin| − K, |emax|) and equal to (1u<<M) - 1, where M is a non-negative integer." – Ben Voigt Jun 24 '16 at 18:23
  • For those who (like me) just want something practical that allows enum values to be bitwise manipulated and doesn't look too ugly with templates and type casting, this is a good solution; just define variables to be type int. – Eric Sokolowsky Jan 24 at 15:37
37

Note if you are working in Windows environment, there is a DEFINE_ENUM_FLAG_OPERATORS macro defined in winnt.h that does the job for you. So in this case, you can do this:

enum AnimalFlags
{
    HasClaws = 1,
    CanFly =2,
    EatsFish = 4,
    Endangered = 8
};
DEFINE_ENUM_FLAG_OPERATORS(AnimalFlags)

seahawk.flags = CanFly | EatsFish | Endangered;
21

I find the currently accepted answer by eidolon too dangerous. The compiler's optimizer might make assumptions about possible values in the enum and you might get garbage back with invalid values. And usually nobody wants to define all possible permutations in flags enums.

As Brian R. Bondy states below, if you're using C++11 (which everyone should, it's that good) you can now do this more easily with enum class:

enum class ObjectType : uint32_t
{
    ANIMAL = (1 << 0),
    VEGETABLE = (1 << 1),
    MINERAL = (1 << 2)
};


constexpr enum ObjectType operator |( const enum ObjectType selfValue, const enum ObjectType inValue )
{
    return (enum ObjectType)(uint32_t(selfValue) | uint32_t(inValue));
}

// ... add more operators here. 

This ensures a stable size and value range by specifying a type for the enum, inhibits automatic downcasting of enums to ints etc. by using enum class, and uses constexpr to ensure the code for the operators gets inlined and thus just as fast as regular numbers.

For people stuck with pre-11 C++ dialects

If I was stuck with a compiler that doesn't support C++11, I'd go with wrapping an int-type in a class that then permits only use of bitwise operators and the types from that enum to set its values:

template<class ENUM,class UNDERLYING=typename std::underlying_type<ENUM>::type>
class SafeEnum
{
public:
    SafeEnum() : mFlags(0) {}
    SafeEnum( ENUM singleFlag ) : mFlags(singleFlag) {}
    SafeEnum( const SafeEnum& original ) : mFlags(original.mFlags) {}

    SafeEnum&   operator |=( ENUM addValue )    { mFlags |= addValue; return *this; }
    SafeEnum    operator |( ENUM addValue )     { SafeEnum  result(*this); result |= addValue; return result; }
    SafeEnum&   operator &=( ENUM maskValue )   { mFlags &= maskValue; return *this; }
    SafeEnum    operator &( ENUM maskValue )    { SafeEnum  result(*this); result &= maskValue; return result; }
    SafeEnum    operator ~()    { SafeEnum  result(*this); result.mFlags = ~result.mFlags; return result; }
    explicit operator bool()                    { return mFlags != 0; }

protected:
    UNDERLYING  mFlags;
};

You can define this pretty much like a regular enum + typedef:

enum TFlags_
{
    EFlagsNone  = 0,
    EFlagOne    = (1 << 0),
    EFlagTwo    = (1 << 1),
    EFlagThree  = (1 << 2),
    EFlagFour   = (1 << 3)
};

typedef SafeEnum<enum TFlags_>  TFlags;

And usage is similar as well:

TFlags      myFlags;

myFlags |= EFlagTwo;
myFlags |= EFlagThree;

if( myFlags & EFlagTwo )
    std::cout << "flag 2 is set" << std::endl;
if( (myFlags & EFlagFour) == EFlagsNone )
    std::cout << "flag 4 is not set" << std::endl;

And you can also override the underlying type for binary-stable enums (like C++11's enum foo : type) using the second template parameter, i.e. typedef SafeEnum<enum TFlags_,uint8_t> TFlags;.

I marked the operator bool override with C++11's explicit keyword to prevent it from resulting in int conversions, as those could cause sets of flags to end up collapsed into 0 or 1 when writing them out. If you can't use C++11, leave that overload out and rewrite the first conditional in the example usage as (myFlags & EFlagTwo) == EFlagTwo.

17

Easiest way to do this as shown here, using the standard library class bitset.

To emulate the C# feature in a type-safe way, you'd have to write a template wrapper around the bitset, replacing the int arguments with an enum given as a type parameter to the template. Something like:

    template <class T, int N>
class FlagSet
{

    bitset<N> bits;

    FlagSet(T enumVal)
    {
        bits.set(enumVal);
    }

    // etc.
};

enum MyFlags
{
    FLAG_ONE,
    FLAG_TWO
};

FlagSet<MyFlags, 2> myFlag;
11

In my opinion none of the answers so far are ideal. To be ideal I would expect the solution:

  1. Support the ==,!=,=,&,&=,|,|= and ~ operators in the conventional sense (i.e. a & b)
  2. Be type safe i.e. not permit non-enumerated values such as literals or integer types to be assigned (except for bitwise combinations of enumerated values) or allow an enum variable to be assigned to an integer type
  3. Permit expressions such as if (a & b)...
  4. Not require evil macros, implementation specific features or other hacks

Most of the solutions thus far fall over on points 2 or 3. WebDancer's is the closes in my opinion but fails at point 3 and needs to be repeated for every enum.

My proposed solution is a generalized version of WebDancer's that also addresses point 3:

#include <cstdint>
#include <type_traits>

template<typename T = typename std::enable_if<std::is_enum<T>::value, T>::type>
class auto_bool
{
    T val_;
public:
    constexpr auto_bool(T val) : val_(val) {}
    constexpr operator T() const { return val_; }
    constexpr explicit operator bool() const
    {
        return static_cast<std::underlying_type_t<T>>(val_) != 0;
    }
};

template <typename T = typename std::enable_if<std::is_enum<T>::value, T>::type>
constexpr auto_bool<T> operator&(T lhs, T rhs)
{
    return static_cast<T>(
        static_cast<typename std::underlying_type<T>::type>(lhs) &
        static_cast<typename std::underlying_type<T>::type>(rhs));
}

template <typename T = typename std::enable_if<std::is_enum<T>::value, T>::type>
constexpr T operator|(T lhs, T rhs)
{
    return static_cast<T>(
        static_cast<typename std::underlying_type<T>::type>(lhs) |
        static_cast<typename std::underlying_type<T>::type>(rhs));
}

enum class AnimalFlags : uint8_t 
{
    HasClaws = 1,
    CanFly = 2,
    EatsFish = 4,
    Endangered = 8
};

enum class PlantFlags : uint8_t
{
    HasLeaves = 1,
    HasFlowers = 2,
    HasFruit = 4,
    HasThorns = 8
};

int main()
{
    AnimalFlags seahawk = AnimalFlags::CanFly;        // Compiles, as expected
    AnimalFlags lion = AnimalFlags::HasClaws;         // Compiles, as expected
    PlantFlags rose = PlantFlags::HasFlowers;         // Compiles, as expected
//  rose = 1;                                         // Won't compile, as expected
    if (seahawk != lion) {}                           // Compiles, as expected
//  if (seahawk == rose) {}                           // Won't compile, as expected
//  seahawk = PlantFlags::HasThorns;                  // Won't compile, as expected
    seahawk = seahawk | AnimalFlags::EatsFish;        // Compiles, as expected
    lion = AnimalFlags::HasClaws |                    // Compiles, as expected
           AnimalFlags::Endangered;
//  int eagle = AnimalFlags::CanFly |                 // Won't compile, as expected
//              AnimalFlags::HasClaws;
//  int has_claws = seahawk & AnimalFlags::CanFly;    // Won't compile, as expected
    if (seahawk & AnimalFlags::CanFly) {}             // Compiles, as expected
    seahawk = seahawk & AnimalFlags::CanFly;          // Compiles, as expected

    return 0;
}

This creates overloads of the necessary operators but uses SFINAE to limit them to enumerated types. Note that in the interests of brevity I haven't defined all of the operators but the only one that is any different is the &. The operators are currently global (i.e. apply to all enumerated types) but this could be reduced either by placing the overloads in a namespace (what I do), or by adding additional SFINAE conditions (perhaps using particular underlying types, or specially created type aliases). The underlying_type_t is a C++14 feature but it seems to be well supported and is easy to emulate for C++11 with a simple template<typename T> using underlying_type_t = underlying_type<T>::type;

  • While your proposed solution works great, it also introduces this pattern for enums that are not meant to be treated as flags. That is probably the reason for the use of (evil) macros like DEFINE_ENUM_FLAG_OPERATORS from Microsoft. – WebDancer Mar 15 '18 at 13:10
  • @WebDancer, you are of course correct, but then I already said that in my answer. I also suggested two ways of addressing the issue -- putting it in a namespace or using a more restrictive SFINAE condition. – Trevor Mar 16 '18 at 18:45
  • My point is unless you make a really narrow namespace (e.g. namespace AllMyFlagEnums) or have a SFINAE condition that in some way selects only a few exact enums the code is broken in my mind. Rather than risking this, I copy&paste a "textual template" where I just replace then enum name, and sometimes the "evil" macros. I wish there was a better way. – WebDancer Mar 19 '18 at 8:51
  • Firstly, it will only cause a problem if elsewhere in your code you need to do one of the things it is intended to stop e.g. assign a literal, integer or an element from another enum. Otherwise the modified enum behaves like a regular enum e.g. the elements do not necessarily need to be powers of two and assignment, comparison and bitwise operations work as normal. If you really must assign literals or mix enums you can still explicitly cast, with the added advantage that your intent will be clearer. So chances are there wouldn't be a need to reduce the scope. – Trevor Mar 19 '18 at 10:51
  • Secondly, if even if you do need to reduce the scope, the namespace may not need to be narrow - although that will depend on what you are doing. If you are working on a library then perhaps you already have your code that depends on the enums in a namespace, then the enum code just goes in the same namespace. If you require the enum behavior for a class (perhaps you want to use the enums as method arguments or member variables of the class) then put the enum code in the class for the same effect. Bottom line is you don't need to wrap a namespace around just the enums - although you could. – Trevor Mar 19 '18 at 11:01
6

I found myself asking the same question and came up with a generic C++11 based solution, similar to soru's:

template <typename TENUM>
class FlagSet {

private:
    using TUNDER = typename std::underlying_type<TENUM>::type;
    std::bitset<std::numeric_limits<TUNDER>::max()> m_flags;

public:
    FlagSet() = default;

    template <typename... ARGS>
    FlagSet(TENUM f, ARGS... args) : FlagSet(args...)
    {   
        set(f);
    }   
    FlagSet& set(TENUM f)
    {   
        m_flags.set(static_cast<TUNDER>(f));
        return *this;
    }   
    bool test(TENUM f)
    {   
        return m_flags.test(static_cast<TUNDER>(f));
    }   
    FlagSet& operator|=(TENUM f)
    {   
        return set(f);
    }   
};

The interface can be improved to taste. Then it can be used like so:

FlagSet<Flags> flags{Flags::FLAG_A, Flags::FLAG_C};
flags |= Flags::FLAG_D;
  • 1
    Look at this for better and more complete code: codereview.stackexchange.com/questions/96146/… – Shital Shah May 30 '16 at 9:12
  • 4
    Except for my use of numeric_limits, the code is almost the same. I guess it is a common way to have a type-safe enum class. I would argue that using numeric_limits is better than putting a SENTINEL at the end of every enum. – Omair May 30 '16 at 10:30
6

The C++ standard explicitly talks about this, see section "17.5.2.1.3 Bitmask types":

http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2012/n3485.pdf

Given this "template" you get:

enum AnimalFlags : unsigned int
{
    HasClaws = 1,
    CanFly = 2,
    EatsFish = 4,
    Endangered = 8
};

constexpr AnimalFlags operator|(AnimalFlags X, AnimalFlags Y) {
    return static_cast<AnimalFlags>(
        static_cast<unsigned int>(X) | static_cast<unsigned int>(Y));
}

AnimalFlags& operator|=(AnimalFlags& X, AnimalFlags Y) {
    X = X | Y; return X;
}

And similar for the other operators. Also note the "constexpr", it is needed if you want the compiler to be able to execute the operators compile time.

If you are using C++/CLI and want to able assign to enum members of ref classes you need to use tracking references instead:

AnimalFlags% operator|=(AnimalFlags% X, AnimalFlags Y) {
    X = X | Y; return X;
}

NOTE: This sample is not complete, see section "17.5.2.1.3 Bitmask types" for a complete set of operators.

5

If your compiler doesn't support strongly typed enums yet, you can give a look to the following article from the c++ source:

From the abstract:

This article presents a solution to the problem of constraining bit operations to
allow only safe and legitimate ones, and turn all invalid bit manipulations into compile-time errors. Best of all, the syntax of bit operations remains unchanged, and the code working with bits does not need to be modified, except possibly to fix errors that had as yet remained undetected.

3

You are confusing objects and collections of objects. Specifically, you are confusing binary flags with sets of binary flags. A proper solution would look like this:

// These are individual flags
enum AnimalFlag // Flag, not Flags
{
    HasClaws = 0,
    CanFly,
    EatsFish,
    Endangered
};

class AnimalFlagSet
{
    int m_Flags;

  public:

    AnimalFlagSet() : m_Flags(0) { }

    void Set( AnimalFlag flag ) { m_Flags |= (1 << flag); }

    void Clear( AnimalFlag flag ) { m_Flags &= ~ (1 << flag); }

    bool Get( AnimalFlag flag ) const { return (m_Flags >> flag) & 1; }

};
3

Here's an option for bitmasks if you don't actually have a use for the individual enum values (ex. you don't need to switch off of them)... and if you aren't worried about maintaining binary compatibility ie: you don't care where your bits live... which you probably are. Also you'd better not be too concerned with scoping and access control. Hmmm, enums have some nice properties for bit-fields... wonder if anyone has ever tried that :)

struct AnimalProperties
{
    bool HasClaws : 1;
    bool CanFly : 1;
    bool EatsFish : 1;
    bool Endangered : 1;
};

union AnimalDescription
{
    AnimalProperties Properties;
    int Flags;
};

void TestUnionFlags()
{
    AnimalDescription propertiesA;
    propertiesA.Properties.CanFly = true;

    AnimalDescription propertiesB = propertiesA;
    propertiesB.Properties.EatsFish = true;

    if( propertiesA.Flags == propertiesB.Flags )
    {
        cout << "Life is terrible :(";
    }
    else
    {
        cout << "Life is great!";
    }

    AnimalDescription propertiesC = propertiesA;
    if( propertiesA.Flags == propertiesC.Flags )
    {
        cout << "Life is great!";
    }
    else
    {
        cout << "Life is terrible :(";
    }
}

We can see that life is great, we have our discrete values, and we have a nice int to & and | to our hearts content, which still has context of what its bits mean. Everything is consistent and predictable... for me... as long as I keep using Microsoft's VC++ compiler w/ Update 3 on Win10 x64 and don't touch my compiler flags :)

Even though everything is great... we have some context as to the meaning of flags now, since its in a union w/ the bitfield in the terrible real world where your program may be be responsible for more than a single discrete task you could still accidentally (quite easily) smash two flags fields of different unions together (say, AnimalProperties and ObjectProperties, since they're both ints), mixing up all yours bits, which is a horrible bug to trace down... and how I know many people on this post don't work with bitmasks very often, since building them is easy and maintaining them is hard.

class AnimalDefinition {
public:
    static AnimalDefinition *GetAnimalDefinition( AnimalFlags flags );   //A little too obvious for my taste... NEXT!
    static AnimalDefinition *GetAnimalDefinition( AnimalProperties properties );   //Oh I see how to use this! BORING, NEXT!
    static AnimalDefinition *GetAnimalDefinition( int flags ); //hmm, wish I could see how to construct a valid "flags" int without CrossFingers+Ctrl+Shift+F("Animal*"). Maybe just hard-code 16 or something?

    AnimalFlags animalFlags;  //Well this is *way* too hard to break unintentionally, screw this!
    int flags; //PERFECT! Nothing will ever go wrong here... 
    //wait, what values are used for this particular flags field? Is this AnimalFlags or ObjectFlags? Or is it RuntimePlatformFlags? Does it matter? Where's the documentation? 
    //Well luckily anyone in the code base and get confused and destroy the whole program! At least I don't need to static_cast anymore, phew!

    private:
    AnimalDescription m_description; //Oh I know what this is. All of the mystery and excitement of life has been stolen away :(
}

So then you make your union declaration private to prevent direct access to "Flags", and have to add getters/setters and operator overloads, then make a macro for all that, and you're basically right back where you started when you tried to do this with an Enum.

Unfortunately if you want your code to be portable, I don't think there is any way to either A) guarantee the bit layout or B) determine the bit layout at compile time (so you can track it and at least correct for changes across versions/platforms etc) Offset in a struct with bit fields

At runtime you can play tricks w/ setting the the fields and XORing the flags to see which bits did change, sounds pretty crappy to me though verses having a 100% consistent, platform independent, and completely deterministic solution ie: an ENUM.

TL;DR: Don't listen to the haters. C++ is not English. Just because the literal definition of an abbreviated keyword inherited from C might not fit your usage doesn't mean you shouldn't use it when the C and C++ definition of the keyword absolutely includes your use case. You can also use structs to model things other than structures, and classes for things other than school and social caste. You may use float for values which are grounded. You may use char for variables which are neither un-burnt nor a person in a novel, play, or movie. Any programmer who goes to the dictionary to determine the meaning of a keyword before the language spec is a... well I'll hold my tongue there.

If you do want your code modeled after spoken language you'd be best off writing in Objective-C, which incidentally also uses enums heavily for bitfields.

3

I'd like to elaborate on Uliwitness answer, fixing his code for C++98 and using the Safe Bool idiom, for lack of the std::underlying_type<> template and the explicit keyword in C++ versions below C++11.

I also modified it so that the enum values can be sequential without any explicit assignment, so you can have

enum AnimalFlags_
{
    HasClaws,
    CanFly,
    EatsFish,
    Endangered
};
typedef FlagsEnum<AnimalFlags_> AnimalFlags;

seahawk.flags = AnimalFlags() | CanFly | EatsFish | Endangered;

You can then get the raw flags value with

seahawk.flags.value();

Here's the code.

template <typename EnumType, typename Underlying = int>
class FlagsEnum
{
    typedef Underlying FlagsEnum::* RestrictedBool;

public:
    FlagsEnum() : m_flags(Underlying()) {}

    FlagsEnum(EnumType singleFlag):
        m_flags(1 << singleFlag)
    {}

    FlagsEnum(const FlagsEnum& original):
        m_flags(original.m_flags)
    {}

    FlagsEnum& operator |=(const FlagsEnum& f) {
        m_flags |= f.m_flags;
        return *this;
    }

    FlagsEnum& operator &=(const FlagsEnum& f) {
        m_flags &= f.m_flags;
        return *this;
    }

    friend FlagsEnum operator |(const FlagsEnum& f1, const FlagsEnum& f2) {
        return FlagsEnum(f1) |= f2;
    }

    friend FlagsEnum operator &(const FlagsEnum& f1, const FlagsEnum& f2) {
        return FlagsEnum(f1) &= f2;
    }

    FlagsEnum operator ~() const {
        FlagsEnum result(*this);
        result.m_flags = ~result.m_flags;
        return result;
    }

    operator RestrictedBool() const {
        return m_flags ? &FlagsEnum::m_flags : 0;
    }

    Underlying value() const {
        return m_flags;
    }

protected:
    Underlying  m_flags;
};
2

As above(Kai) or do the following. Really enums are "Enumerations", what you want to do is have a set, therefore you should really use stl::set

enum AnimalFlags
{
    HasClaws = 1,
    CanFly =2,
    EatsFish = 4,
    Endangered = 8
};

int main(void)
{
    AnimalFlags seahawk;
    //seahawk= CanFly | EatsFish | Endangered;
    seahawk= static_cast<AnimalFlags>(CanFly | EatsFish | Endangered);
}
2

Here is my solution without needing any bunch of overloading or casting:

namespace EFoobar
{
    enum
    {
        FB_A    = 0x1,
        FB_B    = 0x2,
        FB_C    = 0x4,
    };
    typedef long Flags;
}

void Foobar(EFoobar::Flags flags)
{
    if (flags & EFoobar::FB_A)
        // do sth
        ;
    if (flags & EFoobar::FB_B)
        // do sth
        ;
}

void ExampleUsage()
{
    Foobar(EFoobar::FB_A | EFoobar::FB_B);
    EFoobar::Flags otherflags = 0;
    otherflags|= EFoobar::FB_B;
    otherflags&= ~EFoobar::FB_B;
    Foobar(otherflags);
}

I think it's ok, because we identify (non strongly typed) enums and ints anyway.

Just as a (longer) side note, if you

  • want to use strongly typed enums and
  • don't need heavy bit fiddling with your flags
  • performance is not an issue

I would come up with this:

#include <set>

enum class EFoobarFlags
{
    FB_A = 1,
    FB_B,
    FB_C,
};

void Foobar(const std::set<EFoobarFlags>& flags)
{
    if (flags.find(EFoobarFlags::FB_A) != flags.end())
        // do sth
        ;
    if (flags.find(EFoobarFlags::FB_B) != flags.end())
        // do sth
        ;
}

void ExampleUsage()
{
    Foobar({EFoobarFlags::FB_A, EFoobarFlags::FB_B});
    std::set<EFoobarFlags> otherflags{};
    otherflags.insert(EFoobarFlags::FB_B);
    otherflags.erase(EFoobarFlags::FB_B);
    Foobar(otherflags);
}

using C++11 initializer lists and enum class.

  • By the way, I rather wouldn't recommend enums for flags at all. Simple reason: combinations of flags aren't elements of the enum again. So this seems quite unsuitable. Alternatively I would use a using Flags = unsigned long inside a namespace or struct containing the flag values themselves as /*static*/ const Flags XY = 0x01 and so on. – yau Aug 10 '16 at 18:49
2

Currently there is no language support for enum flags, Meta classes might inherently add this feature if it would ever be part of the c++ standard.

My solution would be to create enum-only instantiated template functions adding support for type-safe bitwise operations for enum class using its underlying type:

File: EnumClassBitwise.h

#pragma once
#ifndef _ENUM_CLASS_BITWISE_H_
#define _ENUM_CLASS_BITWISE_H_

#include <type_traits>

//unary ~operator    
template <typename Enum, typename std::enable_if_t<std::is_enum<Enum>::value, int> = 0>
constexpr inline Enum& operator~ (Enum& val)
{
    val = static_cast<Enum>(~static_cast<std::underlying_type_t<Enum>>(val));
    return val;
}

// & operator
template <typename Enum, typename std::enable_if_t<std::is_enum<Enum>::value, int> = 0>
constexpr inline Enum operator& (Enum lhs, Enum rhs)
{
    return static_cast<Enum>(static_cast<std::underlying_type_t<Enum>>(lhs) & static_cast<std::underlying_type_t<Enum>>(rhs));
}

// &= operator
template <typename Enum, typename std::enable_if_t<std::is_enum<Enum>::value, int> = 0>
constexpr inline Enum operator&= (Enum& lhs, Enum rhs)
{
    lhs = static_cast<Enum>(static_cast<std::underlying_type_t<Enum>>(lhs) & static_cast<std::underlying_type_t<Enum>>(rhs));
    return lhs;
}

//| operator

template <typename Enum, typename std::enable_if_t<std::is_enum<Enum>::value, int> = 0>
constexpr inline Enum operator| (Enum lhs, Enum rhs)
{
    return static_cast<Enum>(static_cast<std::underlying_type_t<Enum>>(lhs) | static_cast<std::underlying_type_t<Enum>>(rhs));
}
//|= operator

template <typename Enum, typename std::enable_if_t<std::is_enum<Enum>::value, int> = 0>
constexpr inline Enum& operator|= (Enum& lhs, Enum rhs)
{
    lhs = static_cast<Enum>(static_cast<std::underlying_type_t<Enum>>(lhs) | static_cast<std::underlying_type_t<Enum>>(rhs));
    return lhs;
}

#endif // _ENUM_CLASS_BITWISE_H_

For convenience and for reducing mistakes, you might want to wrap your bit flags operations for enums and for integers as well:

File: BitFlags.h

#pragma once
#ifndef _BIT_FLAGS_H_
#define _BIT_FLAGS_H_

#include "EnumClassBitwise.h"

 template<typename T>
 class BitFlags
 {
 public:

     constexpr inline BitFlags() = default;
     constexpr inline BitFlags(T value) { mValue = value; }
     constexpr inline BitFlags operator| (T rhs) const { return mValue | rhs; }
     constexpr inline BitFlags operator& (T rhs) const { return mValue & rhs; }
     constexpr inline BitFlags operator~ () const { return ~mValue; }
     constexpr inline operator T() const { return mValue; }
     constexpr inline BitFlags& operator|=(T rhs) { mValue |= rhs; return *this; }
     constexpr inline BitFlags& operator&=(T rhs) { mValue &= rhs; return *this; }
     constexpr inline bool test(T rhs) const { return (mValue & rhs) == rhs; }
     constexpr inline void set(T rhs) { mValue |= rhs; }
     constexpr inline void clear(T rhs) { mValue &= ~rhs; }

 private:
     T mValue;
 };
#endif //#define _BIT_FLAGS_H_

Possible usage:

#include <cstdint>
#include <BitFlags.h>
void main()
{
    enum class Options : uint32_t
    { 
          NoOption = 0 << 0
        , Option1  = 1 << 0
        , Option2  = 1 << 1
        , Option3  = 1 << 2
        , Option4  = 1 << 3
    };

    const uint32_t Option1 = 1 << 0;
    const uint32_t Option2 = 1 << 1;
    const uint32_t Option3 = 1 << 2;
    const uint32_t Option4 = 1 << 3;

   //Enum BitFlags
    BitFlags<Options> optionsEnum(Options::NoOption);
    optionsEnum.set(Options::Option1 | Options::Option3);

   //Standard integer BitFlags
    BitFlags<uint32_t> optionsUint32(0);
    optionsUint32.set(Option1 | Option3); 

    return 0;
}
1

Maybe like NS_OPTIONS of Objective-C.

#define ENUM(T1, T2) \
enum class T1 : T2; \
inline T1 operator~ (T1 a) { return (T1)~(int)a; } \
inline T1 operator| (T1 a, T1 b) { return static_cast<T1>((static_cast<T2>(a) | static_cast<T2>(b))); } \
inline T1 operator& (T1 a, T1 b) { return static_cast<T1>((static_cast<T2>(a) & static_cast<T2>(b))); } \
inline T1 operator^ (T1 a, T1 b) { return static_cast<T1>((static_cast<T2>(a) ^ static_cast<T2>(b))); } \
inline T1& operator|= (T1& a, T1 b) { return reinterpret_cast<T1&>((reinterpret_cast<T2&>(a) |= static_cast<T2>(b))); } \
inline T1& operator&= (T1& a, T1 b) { return reinterpret_cast<T1&>((reinterpret_cast<T2&>(a) &= static_cast<T2>(b))); } \
inline T1& operator^= (T1& a, T1 b) { return reinterpret_cast<T1&>((reinterpret_cast<T2&>(a) ^= static_cast<T2>(b))); } \
enum class T1 : T2

ENUM(Options, short) {
    FIRST  = 1 << 0,
    SECOND = 1 << 1,
    THIRD  = 1 << 2,
    FOURTH = 1 << 3
};

auto options = Options::FIRST | Options::SECOND;
options |= Options::THIRD;
if ((options & Options::SECOND) == Options::SECOND)
    cout << "Contains second option." << endl;
if ((options & Options::THIRD) == Options::THIRD)
    cout << "Contains third option." << endl;
return 0;

// Output:
// Contains second option. 
// Contains third option.
  • Can you explain why your answer is the best fit? There are several other answers that have answered this question, so please include some information to differentiate yours. – trevorp Aug 31 '18 at 19:38
-1

Only syntactic sugar. No additional metadata.

namespace UserRole // grupy
{ 
    constexpr uint8_t dea = 1;
    constexpr uint8_t red = 2;
    constexpr uint8_t stu = 4;
    constexpr uint8_t kie = 8;
    constexpr uint8_t adm = 16;
    constexpr uint8_t mas = 32;
}

Flag operators on integral type just works.

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