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Say, I've got the following struct:

typedef struct my_struct{
    unsigned long       a;
    unsigned long       b;
    char*               c;
    unsigned int        d1  :1;
    unsigned int        d2  :4;
    unsigned int        d3  :4;
    unsigned int        d4  :23;
} my_type, *p_type;

The field d3 is currently defined by #defines that reach from 0x00 until 0x0D.

Actually, d3 is an enumeration. So it's tempting to go ahead and replace

    unsigned int        d3  :4;

by

    my_enum             d3  :4;

Is this safe/allowed?

The code has to compile with various

  • compilers (GCC, Visual Studio, embedded stuff)
  • platforms (Win32, Linux, embedded stuff)
  • configurations (compile as C, compile as C++)

Obviously, I could leave the definition of d3 as it is and use the enum in my code, assign it to d3 and so on but that's not going to work with C++.

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How many compilers have you tried this with? –  HonkyTonk Aug 16 '12 at 8:26

3 Answers 3

up vote 7 down vote accepted

Answer will be different for C and C++, this is one for C.

In C bitfields are restricted to signed int, unsigned int, _Bool and int which in this context can be any of the first two. Compiler implementors can add to that list to their liking but are required to document the types that they support.

So to answer your question, if you want to be absolutely sure that your code is portable to all C compilers, no, using an enum type is not an option.

The corresponding paragraph from the current standard reads:

A bit-field shall have a type that is a qualified or unqualified version of _Bool, signed int, unsigned int, or some other implementation-defined type. It is implementation-defined whether atomic types are permitted.

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+1 sometimes a simple "no" could be so alleviative :-) –  eckes Aug 16 '12 at 9:11

It's allowed in all C++ compilers, that supports standard.

C++03 standard 9.6/3

A bit-field shall have integral or enumeration type (3.9.1). It is implementation-defined whether a plain (neither explicitly signed nor unsigned) char, short, int or long bit-field is signed or unsigned.

C++03 standard 9.6/4

If the value of an enu- merator is stored into a bit-field of the same enumeration type and the number of bits in the bit-field is large enough to hold all the values of that enumeration type, the original enumerator value and the value of the bit-field shall compare equal.

example

enum BOOL { f=0, t=1 };
struct A {
BOOL b:1;
};
A a;
void f() {
a.b = t;
if (a.b == t) // shall yield true
{ /* ... */ }
}

But you can't consider that enum has unsigned underlying type.

C++03 standard 7.2/5

The underlying type of an enumeration is an integral type that can represent all the enumerator values defined in the enumeration. It is implementation-defined which integral type is used as the underlying type for an enumeration except that the underlying type shall not be larger than int unless the value of an enu- merator cannot fit in an int or unsigned int

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In C it is an undefined behavior, because a bit-field can only have signed int, int or unsigned int types (or _Bool with C99).

6.5.2.1 :

A bit-field shall have a type that is a qualified or unqualified version of one of int, unsigned int, or signed int. Whether the high-order bit position of a (possibly qualified) “plain” int bit-field is treated as a sign bit is implementation-defined. A bit-field is interpreted as an integral type consisting of the specified number of bits.

Otherwise, some compilers accept it today as an extension (cf. implementation-defined behavior of the extensions in the standard).

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1  
This is not undefined behavior, but a constraint violation. It is part of a section labled "constraint" and the use of "shall" generaly marks constraints in the standard. So a compiler is required to issue a diagnostic if the type is not ok. Second you are citing seemingly an obsolete version of the standard. See my answer for the correct version (I edited it in) which definitively allows implementation specific types to occur. –  Jens Gustedt Aug 16 '12 at 9:11

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