I've seen reinterpret_cast used to apply incrementation to enum classes, and I'd like to know if this usage is acceptable in standard C++.

enum class Foo : int8_t
{
    Bar1,
    Bar2,
    Bar3,
    Bar4,

    First = Bar1,
    Last = Bar4
};

for (Foo foo = Foo::First; foo <= Foo::Last; ++reinterpret_cast<int8_t &>(foo))
{
    ...
}

I know casting to a reference of a base class is safe in case of trivial classes. But since enum classes are not event implicitly converted to their underlying types, I'm not sure if and how the code above would be guaranteed to work in all compilers. Any clues?

  • What happens if Bar1 = 10 and Bar4 =1? - This is not an answer to your question, just a related issue. – Skeen Oct 20 '13 at 11:38
  • 1
    @Skeen you do not use the above pattern, with First and Last, in that case. – Yakk - Adam Nevraumont Oct 20 '13 at 11:41
  • Also what's wrong with static_cast? I do believe that the only non UD thing you can do with a reinterpret casted value is to cast it back! – Skeen Oct 20 '13 at 11:42
  • @Skeen static_cast can't be used when casting to a reference, atleast VC11 doesn't allow it. Since none of the enumerators are explicitly set to a value here I don't think there is any guarantee that they will be ordered, the compiler would be free to set Bar1 = 10 and Bar4 = 1 if it wants to I believe – Dennis Persson Oct 20 '13 at 11:45
up vote 12 down vote accepted
+50

You might want to overload operator ++ for your enum if you really want to iterate its values:

Foo& operator++( Foo& f )
{
    using UT = std::underlying_type< Foo >::type;
    f = static_cast< Foo >( static_cast< UT >( f ) + 1 );
    return f;
}

and use

for (Foo foo = Foo::First; foo != Foo::Last; ++foo)
{
    ...
}

To answer the question of whether or not the reinterpret_cast is allowed, it all starts with 5.2.10/1:

5.2.10 Reinterpret cast [expr.reinterpret.cast]

1 The result of the expression reinterpret_cast<T>(v) is the result of converting the expression v to type T. If T is an lvalue reference type or an rvalue reference to function type, the result is an lvalue; if T is an rvalue reference to object type, the result is an xvalue; otherwise, the result is a prvalue and the lvalue-to-rvalue (4.1), array-to-pointer (4.2), and function-to-pointer (4.3) standard conversions are performed on the expression v. Conversions that can be performed explicitly using reinterpret_cast are listed below. No other conversion can be performed explicitly using reinterpret_cast.

(emphasis mine)

The reinterpretation using references is based on pointers as per 5.2.10/11:

11 A glvalue expression of type T1 can be cast to the type “reference to T2” if an expression of type “pointer to T1” can be explicitly converted to the type “pointer to T2” using a reinterpret_cast. The result refers to the same object as the source glvalue, but with the specified type. [ Note: That is, for lvalues, a reference cast reinterpret_cast<T&>(x) has the same effect as the conversion *reinterpret_cast<T*>(&x) with the built-in & and * operators (and similarly for reinterpret_cast<T&&>(x)). — end note ] No temporary is created, no copy is made, and constructors (12.1) or conversion functions (12.3) are not called.

Which transforms the question from this:

reinterpret_cast<int8_t&>(foo)

to whether this is legal:

*reinterpret_cast<int8_t*>(&foo)

Next stop is 5.2.10/7:

7 An object pointer can be explicitly converted to an object pointer of a different type. When a prvalue v of type “pointer to T1” is converted to the type “pointer to cv T2”, the result is static_cast<cvT2*>(static_cast<cvvoid*>(v)) if both T1 and T2 are standard-layout types (3.9) and the alignment requirements of T2 are no stricter than those of T1, or if either type is void. Converting a prvalue of type “pointer to T1” to the type “pointer to T2” (where T1 and T2 are object types and where the alignment requirements of T2 are no stricter than those of T1) and back to its original type yields the original pointer value. The result of any other such pointer conversion is unspecified.

Given 3.9/9 both int8_t and your enumeration type are standard layout types the question now transformed into:

*static_cast<int8_t*>(static_cast<void*>(&foo))

This is where you are out of luck. static_cast is defined in 5.2.9 and there is nothing which makes the above legal - in fact 5.2.9/5 is a clear hint that it is illegal. The other clauses don't help:

  • 5.2.9/13 requires T* -> void* -> T* where T must be identical (omitting cv)
  • 5.2.9/9 and 5.2.9/10 are not about pointers, but about values
  • 5.2.9/11 is about classes and class hierarchies
  • 5.2.9/12 is about class member pointers

My conclusion from this is that your code

reinterpret_cast<int8_t&>(foo)

is not legal, its behavior is not defined by the standard.

Also note that the above mentioned 5.2.9/9 and 5.2.9/10 are responsible for making the code legal which I gave in the initial answer and which you can still find at the top.

  • That operator++ does not change its argument, so that ++foo does not change foo. – Maxim Egorushkin Oct 20 '13 at 12:09
  • 4
    +1 'is it safe to reinterpret_cast whatever?' is quite often the wrong formulation of 'why the heck do I think this is a use case for reinterpret_cast?' – R. Martinho Fernandes Oct 20 '13 at 16:17
  • Thanks @Daniel, I appreciate your research effort. This wouldn't change to your conclusion, but is &foo really an object pointer? Looking at the spec, I'm not sure... – GOTO 0 Nov 15 '13 at 8:59
  • @GOTO0 &foo is a pointer to your enum (which is an object), e.g., Foo*. Or am I misreading your question? – Daniel Frey Nov 15 '13 at 15:55
  • @DanielFrey Is an enum class constant an object? I'm confused because unscoped enums are integers. – GOTO 0 Nov 15 '13 at 16:19

The increment accesses the value of foo through an lvalue of a different type, which is undefined behaviour except in the cases listed in 3.10 [basic.lval]. Enumeration types and their underlying types are not in that list, so the code has undefined behaviour.

With some compilers that support non-standard extensions you can do it via type-punning:

union intenum
{
    int8_t i;
    Foo    e;
};

intenum ie;
for (ie.e = Foo::First; ie.e <= Foo::Last; ++ie.i)
  // ...

but this is not portable either, because accessing intenum::i after storing a value in intenum::e is not allowed by the standard.

But why not just use an integer and convert as needed?

for (int8_t i = static_cast<int8_t>(Foo::First);
     i <= static_cast<int8_t>(Foo::Last);
     ++i)
{
  Foo e = static_cast<Foo>(i);
  // ...
}

This is portable and safe.

(It's still not a good idea IMHO, because there could be several enumerators with the same value, or values of the enumeration type that have no corresponding enumerator label.)

It is safe as long as it casts to the exact underlying type of the enum.

If the underlying type of the enum class changes that ++reinterpret_cast<int8_t &>(foo) breaks silently.

A safer version:

foo = static_cast<Foo>(static_cast<std::underlying_type<Foo>::type>(foo) + 1);

Or,

++reinterpret_cast<std::underlying_type<Foo>::type&>(foo);
  • This breaks when the underlying type is larger than int. – orlp Oct 20 '13 at 12:05
  • @nightcracker it does indeed – Maxim Egorushkin Oct 20 '13 at 12:06
  • 4
    You can use static_cast<Foo>(static_cast<typename std::underlying_type<Foo>::type>(foo) + 1). It does require C++11 however. – orlp Oct 20 '13 at 12:06
  • @nightcracker Thanks for std::underlying_type<>, did not know it existed. – Maxim Egorushkin Oct 20 '13 at 12:07
  • 1
    Or a helper function: template<class T> T inc_enum(T x) { return static_cast<T>(static_cast<typename std::underlying_type<T>::type>(x) + 1); } – orlp Oct 20 '13 at 12:08

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