#include <iostream>

struct a {
  enum LOCAL_A { A1, A2 };
enum class b { B1, B2 };

int foo(int input) { return input; }

int main(void) {
  std::cout << foo(a::A1) << std::endl;
  std::cout << foo(static_cast<int>(b::B2)) << std::endl;

The a::LOCAL_A is what the strongly typed enum is trying to achieve, but there is a small difference : normal enums can be converted into integer type, while strongly typed enums can not do it without a cast.

So, is there a way to convert a strongly typed enum value into an integer type without a cast? If yes, how?

11 Answers 11


Strongly typed enums aiming to solve multiple problems and not only scoping problem as you mentioned in your question:

  1. Provide type safety, thus eliminating implicit conversion to integer by integral promotion.
  2. Specify underlying types.
  3. Provide strong scoping.

Thus, it is impossible to implicitly convert a strongly typed enum to integers, or even its underlying type - that's the idea. So you have to use static_cast to make conversion explicit.

If your only problem is scoping and you really want to have implicit promotion to integers, then you better off using not strongly typed enum with the scope of the structure it is declared in.

| improve this answer | |
  • 2
    That's another weird example of 'we know better what you want to do' from C++ creators. Conventional (old-style) enums had tons of benefits like implicit conversion to indexes, seamless using of bitwise operations etc.. The new style enums added a really great scoping thing, but... You cannot use just that thing (even with explicit underlying type specification!). So now you're either forced to use old style enums with tricks like putting them into struct or create ugliest workarounds for new enums like creating your own wrapper around std::vector just to overcome that CAST thing. no comments – avtomaton Jun 10 at 12:35
  • @avtomaton: You should be aware that regular enums also have scoping in C++11. Yes, they dump their enumerators out into the global scope (for backwards compatibility reasons), but you are permitted to access them through the scope of their enumeration name. "create ugliest workarounds for new enums like creating your own wrapper around std::vector just to overcome that CAST thing" Or... just type static_cast. You'll make your code make a lot more sense. – Nicol Bolas Aug 2 at 22:19
  • @NicolBolas You are permitted to access the regular enums through the scope even before c++11, but you are also permitted to access them without it as well even in c++11. Using static_cast just makes the code to look ugly and less readable. Why should I do that if I explicitly specify the underlying type? That was so elegant and beautiful solutions with old-style enums, and the problem was their scope. The new one added scope, but removed the power of binary masks and direct value comparison. For me that's weird. And the amount of that kind of questions clearly shows that not only for me – avtomaton Aug 4 at 23:03
  • @avtomaton: "You are permitted to access the regular enums through the scope even before c++11" No, you can't. – Nicol Bolas Aug 4 at 23:08
  • @NicolBolas my bad, you're right, thank you for pointing on that. But that backward compatibility in c++11 encourages to use it without the scope (I've seen tons of that code with and without the scope across the sources). I'm trying to say that there is no human way to use integer-based enums supporting integer operations without any hack (like explicit casts, or wrapping in a struct, or whatever). And I still have to use old enums (and I'm wrapping them in a struct to FORCE using that artificial scope name) – avtomaton Aug 4 at 23:22

As others have said, you can't have an implicit conversion, and that's by-design.

If you want you can avoid the need to specify the underlying type in the cast.

template <typename E>
constexpr typename std::underlying_type<E>::type to_underlying(E e) noexcept {
    return static_cast<typename std::underlying_type<E>::type>(e);

std::cout << foo(to_underlying(b::B2)) << std::endl;
| improve this answer | |

A C++14 version of the answer provided by R. Martinho Fernandes would be:

#include <type_traits>

template <typename E>
constexpr auto to_underlying(E e) noexcept
    return static_cast<std::underlying_type_t<E>>(e);

As with the previous answer, this will work with any kind of enum and underlying type. I have added the noexcept keyword as it will never throw an exception.

This also appears in Effective Modern C++ by Scott Meyers. See item 10 (it is detailed in the final pages of the item within my copy of the book).

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#include <cstdlib>
#include <cstdio>
#include <cstdint>

#include <type_traits>

namespace utils

namespace details

template< typename E >
using enable_enum_t = typename std::enable_if< std::is_enum<E>::value, 
                                               typename std::underlying_type<E>::type 

}   // namespace details

template< typename E >
constexpr inline details::enable_enum_t<E> underlying_value( E e )noexcept
    return static_cast< typename std::underlying_type<E>::type >( e );

template< typename E , typename T>
constexpr inline typename std::enable_if< std::is_enum<E>::value &&
                                          std::is_integral<T>::value, E
 to_enum( T value ) noexcept 
     return static_cast<E>( value );

} // namespace utils

int main()
    enum class E{ a = 1, b = 3, c = 5 };

    constexpr auto a = utils::underlying_value(E::a);
    constexpr E    b = utils::to_enum<E>(5);
    constexpr auto bv = utils::underlying_value(b);

    printf("a = %d, b = %d", a,bv);
    return 0;
| improve this answer | |
  • 4
    This does not reduce typing or make code cleaner and has the side effects of making it tougher to find such implicit conversions in big projects. Static_cast would be easier to search project wide than these constructs. – Atul Kumar Mar 20 '15 at 20:54
  • 3
    @AtulKumar How is searching for static_cast easier than searching for to_enum? – Johann Gerell Jan 3 '19 at 14:10
  • 2
    This answer needs some explanation and documentation. – Lightness Races in Orbit Aug 14 '19 at 13:07

No. There is no natural way.

In fact, one of the motivations behind having strongly typed enum class in C++11 is to prevent their silent conversion to int.

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  • Have a look at the reply from Khurshid Normuradov. It comes the 'natural way' and is much as intended in 'The C++ Programming Language (4th ed.)'. It does not come in an 'automatic way', and that is good about it. – PapaAtHome Jan 10 '15 at 16:32
  • @PapaAtHome I do not understand the benefit of that over static_cast. Not much change in the typing or code cleanness. What is natural way here? A function returning value? – Atul Kumar Mar 20 '15 at 20:56
  • 1
    @user2876962 The benefit, for me, is that it is not automatic or 'silent' as Iammilind puts it. That prevents dificult to find errors. You can still do a cast but you are forced to think about it. That way you know what you're doing. To me it is part of a 'safe coding' habit. I prefer that no conversions are not done automatic is there is a sliver of a chance that it might introduce an error. Quite a few changes in C++11 related to the type system fall in this category if you ask me. – PapaAtHome Mar 23 '15 at 18:52

The reason for the absence of implicit conversion (by design) was given in other answers.

I personally use unary operator+ for the conversion from enum classes to their underlying type:

template <typename T>
constexpr auto operator+(T e) noexcept
    -> std::enable_if_t<std::is_enum<T>::value, std::underlying_type_t<T>>
    return static_cast<std::underlying_type_t<T>>(e);

Which gives quite little "typing overhead":

std::cout << foo(+b::B2) << std::endl;

Where I actually use a macro to create enums and the operator functions in one shot.

#define UNSIGNED_ENUM_CLASS(name, ...) enum class name : unsigned { __VA_ARGS__ };\
inline constexpr unsigned operator+ (name const val) { return static_cast<unsigned>(val); }
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Short answer is you can't as above posts point out. But for my case, I simply didn't want to clutter the namespace but still have implicit conversions, so I just did:

#include <iostream>

using namespace std;

namespace Foo {
   enum Foo { bar, baz };

int main() {
   cout << Foo::bar << endl; // 0
   cout << Foo::baz << endl; // 1
   return 0;

The namespacing sort of adds a layer of type-safety while I don't have to static cast any enum values to the underlying type.

| improve this answer | |
  • 4
    It adds no type safety whatsoever (indeed, you just removed the type safety) - it only adds name scoping. – Lightness Races in Orbit Aug 14 '19 at 13:09
  • @LightnessRacesinOrbit yes I agree. I lied. Technically, to be exact, the type is just underneath a name space/scope and fully qualifies to Foo::Foo. Members can be accessed as Foo::bar and Foo::baz and can be implicitly casted (and so not much type safety). It's probably better to almost always use enum classes especially if starting a new project. – solstice333 Oct 22 '19 at 1:16

Hope this helps you or someone else

enum class EnumClass : int //set size for enum
    Zero, One, Two, Three, Four

union Union //This will allow us to convert
    EnumClass ec;
    int i;

int main()
using namespace std;

//convert from strongly typed enum to int

Union un2;
un2.ec = EnumClass::Three;

cout << "un2.i = " << un2.i << endl;

//convert from int to strongly typed enum
Union un;
un.i = 0; 

if(un.ec == EnumClass::Zero) cout << "True" << endl;

return 0;
| improve this answer | |
  • 35
    This is called "type punning" and although supported by some compilers is not portable, as the C++ standard says that after you set un.i that is the "active member" and you can only read the active member of a union. – Jonathan Wakely May 2 '14 at 12:49
  • 7
    @JonathanWakely You are technically correct, but I have never seen a compiler where this doesn't work reliably. Stuff like this, anonymous unions, and #pragma once are defacto standards. – BigSandwich Mar 26 '15 at 15:43
  • 7
    Why use something that the standard explicitly forbids, when a simple cast will do? This is just wrong. – Paul Groke Jul 24 '16 at 23:40
  • 1
    Technically correct or not, for me it's way more readable then other solutions found here. And what is more important for me, it can be used to solve not only serialization, but also deserialization of enum class with ease, and readable format. – Marcin Waśniowski Mar 21 '17 at 21:38
  • 8
    I absolutely despair that there are people who consider this messy undefined behaviour "way more readable" than a simple static_cast. – underscore_d Sep 15 '18 at 15:09

This seems impossible with the native enum class, but probably you can mock a enum class with a class:

In this case,

enum class b

would be equivalent to:

class b {
  int underlying;
  static constexpr int B1 = 0;
  static constexpr int B2 = 1;
  b(int v) : underlying(v) {}
  operator int() {
      return underlying;

This is mostly equivalent to the original enum class. You can directly return b::B1 for in a function with return type b. You can do switch case with it, etc.

And in the spirit of this example you can use templates (possibly together with other things) to generalize and mock any possible object defined by the enum class syntax.

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  • but B1 and B2 must be defined outside the class... or this is unusable for case - header.h <-- class b - main.cpp <---- myvector.push_back( B1 ) – Fl0 Nov 6 '18 at 17:35
  • Shouldn't that be "static constexpr b" instead of "static constexpr int'? Otherwise, b::B1 is just an int with no typesafety at all. – Some Guy Apr 30 at 20:34

As many said, there is no way to automatically convert without adding overheads and too much complexity, but you can reduce your typing a bit and make it look better by using lambdas if some cast will be used a bit much in a scenario. That would add a bit of function overhead call, but will make code more readable compared to long static_cast strings as can be seen below. This may not be useful project wide, but only class wide.

#include <bitset>
#include <vector>

enum class Flags { ......, Total };
std::bitset<static_cast<unsigned int>(Total)> MaskVar;
std::vector<Flags> NewFlags;

auto scui = [](Flags a){return static_cast<unsigned int>(a); };

for (auto const& it : NewFlags)
    switch (it)
    case Flags::Horizontal:
        MaskVar.reset(scui(Flags::Vertical)); break;
    case Flags::Vertical:
        MaskVar.reset(scui(Flags::Horizontal)); break;

   case Flags::LongText:
        MaskVar.reset(scui(Flags::ShorTText)); break;
    case Flags::ShorTText:
        MaskVar.reset(scui(Flags::LongText)); break;

    case Flags::ShowHeading:
        MaskVar.reset(scui(Flags::NoShowHeading)); break;
    case Flags::NoShowHeading:
        MaskVar.reset(scui(Flags::ShowHeading)); break;

| improve this answer | |

The C++ committee took one step forward (scoping enums out of global namespace) and fifty steps back (no enum type decay to integer). Sadly, enum class is simply not usable if you need the value of the enum in any non-symbolic way.

The best solution is to not use it at all, and instead scope the enum yourself using a namespace or a struct. For this purpose, they are interchangable. You will need to type a little extra when refering to the enum type itself, but that will likely not be often.

struct TextureUploadFormat {
    enum Type : uint32 {

// must use ::Type, which is the extra typing with this method; beats all the static_cast<>()
uint32 getFormatStride(TextureUploadFormat::Type format){
    const uint32 formatStride[TextureUploadFormat::__count] = {
    return formatStride[format]; // decays without complaint
| improve this answer | |
  • Nice explanation. Is there any single advantage of enum class over enums within namespace or a struct? – Sujay Phadke Sep 28 at 4:20

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