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I was under the impression that accessing an union member other than the last one set is UB, but I can't seem to find a solid reference (other than answers claiming it's UB but without any support from the standard).

So, is it undefined behavior?

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C99 (and I believe C++11 as well) explicitly allow type-punning with unions. So I think it falls under "implementation defined" behavior. –  Mysticial Jul 7 '12 at 7:40
    
I have used it on several occasions to convert from individual int to char. So, I definitely know it is not undefined. I used it on the Sun CC compiler. So, it might still be compiler dependent. –  go4sri Jul 7 '12 at 7:55
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@go4sri: Clearly, you don't know what it means for behavior to be undefined. The fact that it appeared to work for you in some instance does not contradict its undefinededness. –  Benjamin Lindley Jul 7 '12 at 7:58
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This might be a good read: davmac.wordpress.com/2010/02/26/c99-revisited –  Mysticial Jul 7 '12 at 8:03
    
Related: Purpose of Unions in C and C++ –  legends2k Oct 11 '13 at 5:11
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6 Answers

up vote 27 down vote accepted
+100

The confusion is that C explicitly permits type-punning through a union, whereas C++ () has no such permission.

6.5.2.3 Structure and union members

95) If the member used to read the contents of a union object is not the same as the member last used to store a value in the object, the appropriate part of the object representation of the value is reinterpreted as an object representation in the new type as described in 6.2.6 (a process sometimes called ‘‘type punning’’). This might be a trap representation.

The situation with C++:

9.5 Unions [class.union]

In a union, at most one of the non-static data members can be active at any time, that is, the value of at most one of the non-static data members can be stored in a union at any time.

C++ later has language permitting the use of unions containing structs with common initial sequences; this doesn't however permit type-punning.

To determine whether union type-punning is allowed in C++, we have to search further. Recall that is a normative reference for C++11 (and C99 has similar language to C11 permitting union type-punning):

3.9 Types [basic.types]

4 - The object representation of an object of type T is the sequence of N unsigned char objects taken up by the object of type T, where N equals sizeof(T). The value representation of an object is the set of bits that hold the value of type T. For trivially copyable types, the value representation is a set of bits in the object representation that determines a value, which is one discrete element of an implementation-defined set of values. 42
42) The intent is that the memory model of C++ is compatible with that of ISO/IEC 9899 Programming Language C.

It gets particularly interesting when we read

3.8 Object lifetime [basic.life]

The lifetime of an object of type T begins when: — storage with the proper alignment and size for type T is obtained, and — if the object has non-trivial initialization, its initialization is complete.

So for a primitive type (which ipso facto has trivial initialization) contained in a union, the lifetime of the object encompasses at least the lifetime of the union itself. This allows us to invoke

3.9.2 Compound types [basic.compound]

If an object of type T is located at an address A, a pointer of type cv T* whose value is the address A is said to point to that object, regardless of how the value was obtained.

Assuming that the operation we are interested in is type-punning i.e. taking the value of a non-active union member, and given per the above that we have a valid reference to the object referred to by that member, that operation is lvalue-to-rvalue conversion:

4.1 Lvalue-to-rvalue conversion [conv.lval]

A glvalue of a non-function, non-array type T can be converted to a prvalue. If T is an incomplete type, a program that necessitates this conversion is ill-formed. If the object to which the glvalue refers is not an object of type T and is not an object of a type derived from T, or if the object is uninitialized, a program that necessitates this conversion has undefined behavior.

The question then is whether an object that is a non-active union member is initialized by storage to the active union member. As far as I can tell, this is not the case and so although if:

  • a union is copied into char array storage and back (3.9:2), or
  • a union is bytewise copied to another union of the same type (3.9:3), or
  • a union is accessed across language boundaries by a program element conforming to ISO/IEC 9899 (so far as that is defined) (3.9:4 note 42), then

the access to a union by a non-active member is defined and is defined to follow the object and value representation, access without one of the above interpositions is undefined behaviour. This has implications for the optimisations allowed to be performed on such a program, as the implementation may of course assume that undefined behaviour does not occur.

That is, although we can legitimately form an lvalue to a non-active union member (which is why assigning to a non-active member without construction is ok) it is considered to be uninitialized.

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If I am not mistaken (I only have a draft version of the C99 standard), this explicit paragraph about type punning was not in C99. Though, maybe we can infer it from other information in the standard as you did it for C++. Nevertheless, this addition seems to reveal that it was not clear in previous versions of the standard. –  mpu Aug 17 '12 at 9:55
    
@mpu it should be present; look for 6.5.2.3, footnote 82. –  ecatmur Aug 17 '12 at 10:06
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3.8/1 says an object's lifetime ends when its storage is reused. That indicates to me that a non-active member of a union's lifetime has ended because its storage has been reused for the active member. That would mean you're limited in how you use the member (3.8/6). –  bames53 Oct 18 '12 at 19:35
    
@bames53 good point, but if it has trivial initialization then its lifetime starts again immediately or when the non-active member is accessed (storage with the proper alignment and size for type T is obtained). –  ecatmur Oct 19 '12 at 8:05
    
Under that interpretation then every bit of memory simultaneously contains objects of all types that are trivially initiallizable and have appropriate alignment... So then does the lifetime of any non-trivially initiallizable type immediately end as its storage is reused for all these other types (and not restart because they're not trivially initiallizable)? –  bames53 Oct 19 '12 at 14:08
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The C++11 standard says it this way

9.5 Unions

In a union, at most one of the non-static data members can be active at any time, that is, the value of at most one of the non-static data members can be stored in a union at any time.

If only one value is stored, how can you read another? It just isn't there.


The gcc documentation lists this under Implementation defined behavior

  • A member of a union object is accessed using a member of a different type (C90 6.3.2.3).

The relevant bytes of the representation of the object are treated as an object of the type used for the access. See Type-punning. This may be a trap representation.

indicating that this is not required by the C standard.

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@LuchianGrigore: UB isn't what standard says is UB, instead it's what the standard doesn't describe how it should work. This is exactly such case. Does the standard describe what happens? Does it say that it's implementation defined? No and no. So it's UB. Moreover, regarding the "members share the same memory address" argument, you'll have to refer to the aliasing rules, which will bring you to UB again. –  ybungalobill Jul 7 '12 at 7:52
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@Luchian: It's quite clear what active means, "that is, the value of at most one of the non-static data members can be stored in a union at any time." –  Benjamin Lindley Jul 7 '12 at 7:55
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@LuchianGrigore: Yes there are. There is infinite amount of cases that the standard does not (and cannot) address. (C++ is a Turing complete VM so it's incomplete.) So what? It does explain what "active" mean, refer to the above quote, after "that is". –  ybungalobill Jul 7 '12 at 7:55
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It is undefined behaviour to try to read an object that isn't there (like using a dangling pointer). The union only contains one value, the one last written to. –  Bo Persson Jul 7 '12 at 7:56
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@LuchianGrigore: Omission of explicit definition of behavior is also unconsidered undefined behavior, according to the definitions section. –  jxh Jul 7 '12 at 7:59
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I think the closest the standard comes to saying it's undefined behavior is where it defines the behavior for a union containing a common initial sequence (C99, §6.5.2.3/5):

One special guarantee is made in order to simplify the use of unions: if a union contains several structures that share a common initial sequence (see below), and if the union object currently contains one of these structures, it is permitted to inspect the common initial part of any of them anywhere that a declaration of the complete type of the union is visible. Two structures share a common initial sequence if corresponding members have compatible types (and, for bit-fields, the same widths) for a sequence of one or more initial members.

C++11 gives similar requirements/permission at §9.2/19:

If a standard-layout union contains two or more standard-layout structs that share a common initial sequence, and if the standard-layout union object currently contains one of these standard-layout structs, it is permitted to inspect the common initial part of any of them. Two standard-layout structs share a common initial sequence if corresponding members have layout-compatible types and either neither member is a bit-field or both are bit-fields with the same width for a sequence of one or more initial members.

Though neither states it directly, these both carry a strong implication that "inspecting" (reading) a member is "permitted" only if 1) it is (part of) the member most recently written, or 2) is part of a common initial sequence.

That's not a direct statement that doing otherwise is undefined behavior, but it's the closest of which I'm aware.

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To make this complete, you need to know what "layout-compatible types" are for C++, or "compatible types" are for C. –  Michael Anderson Aug 15 '12 at 8:32
    
@MichaelAnderson: Yes and no. You need to deal with those when/if you want to be certain whether something falls within this exception -- but the real question here is whether something that clearly falls outside the exception truly gives UB. I think that's strongly enough implied here to make the intent clear, but I don't think it's ever directly stated. –  Jerry Coffin Aug 15 '12 at 15:43
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Something that is not yet mentioned by available answers is the footnote 37 in the paragraph 21 of the section 6.2.5:

Note that aggregate type does not include union type because an object with union type can only contain one member at a time.

This requirement seem to clearly imply that you must not write in a member and read in another one. In this case it might be undefined behavior by lack of specification.

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That's a good point. –  Luchian Grigore Aug 17 '12 at 3:42
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In C++, we currently have defective rules for object lifetime, which prevents us to properly say that this is OK or not OK according to the Standard. To demonstrate, the Standard says that an object of type T becomes alive if

  • storage with the proper alignment and size for type T is obtained, and
  • if the object has non-trivial initialization, its initialization is complete

The second bullet is never active for types like int. What follows is that the following has undefined behavior

int *p = malloc(sizeof(int) + sizeof(float));
// between these lines, there is already both at least an int and a float object!
*p = 10;
int x = *p;

Why? Because you are reading a float object by the use of an int lvalue - this is not allowed by the aliasing rules. This inconsistent/illogical definition of object lifetime currently is tried to be fixed by http://www.open-std.org/jtc1/sc22/wg21/docs/cwg_active.html#1116 , but until we have a sane definition, we can't say something definite.

In practice, I believe that the rules are, greatly simplified (which is meant to say - contains a lot of missing details needed to be used in practice), interpreted as follows

An object of non-class type T becomes alive if

  • storage with the proper alignment and size for type T is obtained, and
    • the storage comes from a new-expression, variable or object non-union data member definition, or was created for a temporay object, or if not that,
    • a write by an lvalue of type T to that location has been done

The last bullet would need to handle writes by a volatile T, when the object is non-volatile - does the object then become volatile too? And also needs to handle writes by const T* lvalues to T* objects, and some more special cases - we probably don't want to change the type of the target location!

This mechanism provides the rules by which unions can work. If you write into one member, we bring an object of the type of the data member alive. If the type of the other data member is aliasing compatible, we can still read that object by use of the other data members type, in my opinion, because I can find nowhere in the Standard that explicitly forbids it (the phrase that an union can store the value of only one member at a time is not such a rule - that situation is the same for every other plain variable - and still we can apply the aliasing rule to all of them!).

union A {
  int *p;
  const int *q;
};

int main() {
  int x = 10;
  A y = { &x };
  int *r = y.q; // valid per 3.10p10bullet3
}
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I well explain this with a example.
assume we have the following union:

union A{
   int x;
   short y[2];
};

I well assume that sizeof(int) gives 4, and that sizeof(short) gives 2.
when you write union A a = {10} that well create a new var of type A in put in it the value 10.

your memory should look like that: (remember that all of the union members get the same location)

       |                   x                   |
       |        y[0]       |       y[1]        |
       -----------------------------------------
   a-> |0000 0000|0000 0000|0000 0000|0000 1010|
       -----------------------------------------

as you could see, the value of a.x is 10, the value of a.y1 is 10, and the value of a.y[0] is 0.

now, what well happen if I do this?

a.y[0] = 37;

are memory well look like this:

       |                   x                   |
       |        y[0]       |       y[1]        |
       -----------------------------------------
   a-> |0000 0000|0010 0101|0000 0000|0000 1010|
       -----------------------------------------

this well torn the value of a.x to 2424842 (in decimal).

now, if your union has a float, or double, your memory map well be more of a mess, because of the way you store exact numbers. more info you could get in here.

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:) This is not what I asked. I know what happens internally. I know it works. I asked whether it's in the standard. –  Luchian Grigore Aug 17 '12 at 7:08
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