7

I believe that until C++14 a bit field of a struct declared as int was still interpreted as either signed or unsigned, the interpretation being implementation defined. Reference: http://en.cppreference.com/w/cpp/language/bit_field.

Is this still the case in C++14? I.e., is the code below guaranteed to work as inteded?

#include <iostream>

struct X
{
    int f:3;
};

int main() 
{
    X x;
    x.f = -2; // is this going to be indeed signed? It seems so.
    std::cout << x.f << std::endl; // displays -2
}
4
  • 4
    CWG 739. It's a DR.
    – T.C.
    Nov 15, 2015 at 20:51
  • @T.C. How come you know all these DRs -- o.O (also, please consider posting an answer. This is helpful)
    – sehe
    Nov 15, 2015 at 21:24
  • @sehe I'm also asking myself the same thing :)
    – vsoftco
    Nov 15, 2015 at 21:25
  • @sehe Nothing easier than that. There is close to no skill required to find DRs corresponding to a section (or topic) of the standard.
    – Columbo
    Nov 15, 2015 at 21:29

1 Answer 1

5

According to C++11 standard §9.6/p3 Bit-fields [class.bit] (Emphasis Mine):

A bit-field shall not be a static member. 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, long, or long long bit-field is signed or unsigned. A bool value can successfully be stored in a bit-field of any nonzero size. The address-of operator & shall not be applied to a bit-field, so there are no pointers to bitfields. A non-const reference shall not be bound to a bit-field (8.5.3). [ Note: If the initializer for a reference of type const T& is an lvalue that refers to a bit-field, the reference is bound to a temporary initialized to hold the value of the bit-field; the reference is not bound to the bit-field directly. See 8.5.3. —end note ]

So you're correct for the first part. Indeed until C++14 a bit field of a struct not specifically declared as signed was still interpreted as either signed or unsigned, the interpretation being implementation defined.

As already mentioned in this comments by @T.C. Defect reports referring to the issue were made DR739, DR675. Resulting in the following resolutions in C++14 standard:

The wording "It is implementation-defined whether a plain (neither explicitly signed nor unsigned) char, short, int, long, or long long bit-field is signed or unsigned.", was removed, and the C++14 wording now is:

A bit-field shall not be a static member. A bit-field shall have integral or enumeration type (3.9.1). A bool value can successfully be stored in a bit-field of any nonzero size. The address-of operator & shall not be applied to a bit-field, so there are no pointers to bit-fields. A non-const reference shall not be bound to a bit-field (8.5.3). [ Note: If the initializer for a reference of type const T& is an lvalue that refers to a bit-field, the reference is bound to a temporary initialized to hold the value of the bit-field; the reference is not bound to the bit-field directly. See 8.5.3. —end note ]

Also in §C.1.8 Clause 9: classes [diff.class] the following section was added:

9.6

Change: Bit-fields of type plain int are signed.

Rationale: Leaving the choice of signedness to implementations could lead to inconsistent definitions of template specializations. For consistency, the implementation freedom was eliminated for non-dependent types, too.

Effect on original feature: The choice is implementation-defined in C, but not so in C++.

Difficulty of converting: Syntactic transformation.

How widely used: Seldom.

Consequently, in C++14 bit-fields of type plain int are signed and the code posted is guaranteed to work as intended.

2
  • The green text in CW 739 says that the change only applies to dependent types. Was that text not actually adopted?
    – M.M
    Nov 15, 2015 at 23:44
  • @M.M There are two PRs for that DR. The February 2012 one is the one applied.
    – T.C.
    Nov 16, 2015 at 0:23

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