Discussions on the mostly un-or-implementation-defined nature of type-punning via a union typically quote the following bits, here via @ecatmur ( https://stackoverflow.com/a/31557852/2757035 ), on an exemption for standard-layout structs having a "common initial sequence" of member types:

C11 ( Structure and union members; Semantics):

[...] 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 completed 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++03 ([class.mem]/16):

If a POD-union contains two or more POD-structs that share a common initial sequence, and if the POD-union object currently contains one of these POD-structs, it is permitted to inspect the common initial part of any of them. Two POD-structs share a common initial sequence if corresponding members have layout-compatible types (and, for bit-fields, the same widths) for a sequence of one or more initial members.

Other versions of the two standards have similar language; since C++11 the terminology used is standard-layout rather than POD.

Since no reinterpretation is required, this isn't really type-punning, just name substitution applied to union member accesses. A proposal for C++17 (the infamous P0137R1) makes this explicit using language like 'the access is as if the other struct member was nominated'.

But please note the bold - "anywhere that a declaration of the completed type of the union is visible" - a clause that exists in C11 but nowhere in C++ drafts for 2003, 2011, or 2014 (all nearly identical, but later versions replace "POD" with the new term standard layout). In any case, the 'visible declaration of union type bit is totally absent in the corresponding section of any C++ standard.

@loop and @Mints97, here - https://stackoverflow.com/a/28528989/2757035 - show that this line was also absent in C89, first appearing in C99 and remaining in C since then (though, again, never filtering through to C++).

Standards discussions around this

[snipped - see my answer]


From this, then, my questions were:

  • What does this mean? What is classed as a 'visible declaration'? Was this clause intended to narrow down - or expand up - the range of contexts in which such 'punning' has defined behaviour?

  • Are we to assume that this omission in C++ is very deliberate?

  • What is the reason for C++ differing from C? Did C++ just 'inherit' this from C89 and then either decide - or worse, forget - to update alongside C99?

  • If the difference is intentional, then what benefits or drawbacks are there to the 2 different treatments in C vs C++?

  • What, if any, interesting ramifications does it have at compile- or runtime? For example, @ecatmur, in a comment replying to my pointing this out on his original answer (link as above), speculated as follows.

I'd imagine it permits more aggressive optimization; C can assume that function arguments S* s and T* t do not alias even if they share a common initial sequence as long as no union { S; T; } is in view, while C++ can make that assumption only at link time. Might be worth asking a separate question about that difference.

Well, here I am, asking! I'm very interested in any thoughts about this, especially: other relevant parts of the (either) Standard, quotes from committee members or other esteemed commentators, insights from developers who might have noticed a practical difference due to this - assuming any compiler even bothers to enforce C's added clause - and etc. The aim is to generate a useful catalogue of relevant facts about this C clause and its (intentional or not) omission from C++. So, let's go!

  • 5
    FWIW, at -O3, gcc, g++, clang and clang++ all assume that S* and T* arguments do not alias even when a union is in view. This means that a program that passes the aliasing S* and T* union subobjects will behave differently depending on optimization level. Example: coliru.stacked-crooked.com/a/b57c8dd9e2ef3a02 – ecatmur Jan 5 '16 at 17:30
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    Well, I meant discussion as in educated commentary on the questions raised, but I can work on better wording later. – underscore_d Jan 5 '16 at 23:50
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    @ecatmur Very interesting! T is, of course, updated to 42 'in the background' - so the write isn't binned - but the optimiser doesn't reflect that in the return value, as it assumes, given no aliasing, the result must be 5. coliru.stacked-crooked.com/a/04921db9e5f3945a I'd need to test whether this affects me as (A) I'm generally not referring to such unions via pointers and (B) even less am I doing this via functions. There are probably numerous other ways this can bite me if this turns out to be a general behaviour relevant to such unions, though. Will post more findings tomorrow. – underscore_d Jan 5 '16 at 23:57
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    ... and the functions I do have using pointers to union members only take one at a time. What 'scope' is usually applied when deciding whether to ignore/reorder operations that might alias? Assuming it's somewhat broader than 'any function with 2+ pointer arguments', is there a general rule, or is it so UB that anything can happen? – underscore_d Jan 6 '16 at 0:46
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    Aliasing analysis is generally performed at a function level, but functions can be inlined, and whole-program optimization is only getting better. The aliasing exception for character types doesn't apply when the char object is known to be a subobject, so gcc is being over-cautious. – ecatmur Jan 6 '16 at 10:16

I've found my way through the labyrinth to some great sources on this, and I think I've got a pretty comprehensive summary of it. I'm posting this as an answer because it seems to explain both the (IMO very misguided) intention of the C clause and the fact that C++ does not inherit it. This will evolve over time if I discover further supporting material or the situation changes.

This is my first time trying to sum up a very complex situation, which seems ill-defined even to many language architects, so I'll welcome clarifications/suggestions on how to improve this answer - or simply a better answer if anyone has one.

Finally, some concrete commentary

Through vaguely related threads, I found the following answer by @tab - and much appreciated the contained links to (illuminating, if not conclusive) GCC and Working Group defect reports: answer by tab on StackOverflow

The GCC link contains some interesting discussion and reveals a sizeable amount of confusion and conflicting interpretations on part of the Committee and compiler vendors - surrounding the subject of union member structs, punning, and aliasing in both C and C++.

At the end of that, we're linked to the main event - another BugZilla thread, Bug 65892, containing an extremely useful discussion. In particular, we find our way to the first of two pivotal documents:

Origin of the added line in C99

C proposal N685 is the origin of the added clause regarding visibility of a union type declaration. Through what some claim (see GCC thread #2) is a total misinterpretation of the "common initial sequence" allowance, N685 was indeed intended to allow relaxation of aliasing rules for "common initial sequence" structs within a TU aware of some union containing instances of said struct types, as we can see from this quote:

The proposed solution is to require that a union declaration be visible if aliases through a common initial sequence (like the above) are possible. Therefore the following TU provides this kind of aliasing if desired:

union utag {
    struct tag1 { int m1; double d2; } st1;
    struct tag2 { int m1; char c2; } st2;

int similar_func(struct tag1 *pst2, struct tag2 *pst3) {
     pst2->m1 = 2;
     pst3->m1 = 0;   /* might be an alias for pst2->m1 */
     return pst2->m1;

Judging by the GCC discussion and comments below such as @ecatmur's, this proposal - which seems to mandate speculatively allowing aliasing for any struct type that has some instance within some union visible to this TU - seems to have received great derision and rarely been implemented.

It's obvious how difficult it would be to satisfy this interpretation of the added clause without totally crippling many optimisations - for little benefit, as few coders would want this guarantee, and those who do can just turn on fno-strict-aliasing (which IMO indicates larger problems). If implemented, this allowance is more likely to catch people out and spuriously interact with other declarations of unions, than to be useful.

Omission of the line from C++

Following on from this and a comment I made elsewhere, @Potatoswatter in this answer here on SO states that:

The visibility part was purposely omitted from C++ because it's widely considered to be ludicrous and unimplementable.

In other words, it looks like C++ deliberately avoided adopting this added clause, likely due to its widely pereceived absurdity. On asking for an "on the record" citation of this, Potatoswatter provided the following key info about the thread's participants:

The folks in that discussion are essentially "on the record" there. Andrew Pinski is a hardcore GCC backend guy. Martin Sebor is an active C committee member. Jonathan Wakely is an active C++ committee member and language/library implementer. That page is more authoritative, clear, and complete than anything I could write.

Potatoswatter, in the same SO thread linked above, concludes that C++ deliberately excluded this line, leaving no special treatment (or, at best, implementation-defined treatment) for pointers into the common initial sequence. Whether their treatment will in future be specifically defined, versus any other pointers, remains to be seen; compare to my final section below about C. At present, though, it is not (and again, IMO, this is good).

What does this mean for C++ and practical C implementations?

So, with the nefarious line from N685... 'cast aside'... we're back to assuming pointers into the common initial sequence are not special in terms of aliasing. Still. it's worth confirming what this paragraph in C++ means without it. Well, the 2nd GCC thread above links to another gem:

C++ defect 1719. This proposal has reached DRWP status: "A DR issue whose resolution is reflected in the current Working Paper. The Working Paper is a draft for a future version of the Standard" - cite. This is either post C++14 or at least after the final draft I have here (N3797) - and puts forward a significant, and in my opinion illuminating, rewrite of this paragraph's wording, as follows. I'm bolding what I consider to be the important changes, and {these comments} are mine:

In a standard-layout union with an active member {"active" indicates a union instance, not just type} (9.5 [class.union]) of struct type T1, it is permitted to read {formerly "inspect"} a non-static data member m of another union member of struct type T2 provided m is part of the common initial sequence of T1 and T2. [Note: Reading a volatile object through a non-volatile glvalue has undefined behavior ( [dcl.type.cv]). —end note]

This seems to clarify the meaning of the old wording: to me, it says that any specifically allowed 'punning' among union member structs with common initial sequences must be done via an instance of the parent union - rather than being based on the type of the structs (e.g. pointers to them passed to some function). This wording seems to rule out any other interpretation, a la N685. C would do well to adopt this, I'd say. Hey, speaking of which, see below!

The upshot is that - as nicely demonstrated by @ecatmur and in the GCC tickets - this leaves such union member structs by definition in C++, and practically in C, subject to the same strict aliasing rules as any other 2 officially unrelated pointers. The explicit guarantee of being able to read the common initial sequence of inactive union member structs is now more clearly defined, not including vague and unimaginably tedious-to-enforce "visibility" as attempted by N685 for C. By this definition, the main compilers have been behaving as intended for C++. As for C?

Possible reversal of this line in C / clarification in C++

It's also very worth noting that C committee member Martin Sebor is looking to get this fixed in that fine language, too:

Martin Sebor 2015-04-27 14:57:16 UTC If one of you can explain the problem with it I'm willing to write up a paper and submit it to WG14 and request to have the standard changed.

Martin Sebor 2015-05-13 16:02:41 UTC I had a chance to discuss this issue with Clark Nelson last week. Clark has worked on improving the aliasing parts of the C specification in the past, for example in N1520 (http://www.open-std.org/jtc1/sc22/wg14/www/docs/n1520.htm). He agreed that like the issues pointed out in N1520, this is also an outstanding problem that would be worth for WG14 to revisit and fix."

Potatoswatter inspiringly concludes:

The C and C++ committees (via Martin and Clark) will try to find a consensus and hammer out wording so the standard can finally say what it means.

We can only hope!

Again, all further thoughts are welcome.

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    Is there any other Standard means by which code which relies upon the Common Initial Sequence rule can work if structure types don't all have the same alignment, and might not all be defined in the same place (e.g.. foo.h defines a "header" struct whose total member length is not a multiple of alignment; bar.h and boz.h each define a union containing that structure and their own extended version; is there any way to write a function in foo.c which can work accept pointers to the entended structure types from bar.h and boz.h and access the common members thereof?) – supercat Jun 25 '16 at 20:37
  • If gcc didn't want to have to make pessimistic presumptions about aliasing of types that appear in unions, would there have been any problem whatsoever with saying that a union of structure types is an indication that common initial members of those types might alias *absent an __attribute or pragma indicating otherwise? – supercat Jun 25 '16 at 20:39
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    I notice your last edit still suggests that C clause is misguided. I'm still awaiting any practical way of adapting code that relies upon the ability to use a CIS of two types with different sizes and alignment requirements (behavior that used to be universally supported and non-controversial), so as to be defined under gcc's interpretation of the rules. Some compiler writers may not have liked what the rule required, but most of the "optimizations" would curtail would be the phony sort that make code useless. – supercat Sep 7 '16 at 21:34
  • "via an instance of the parent union" What is "via"? – curiousguy May 30 '18 at 3:48
  • Accessing the struct using an expression that gets it as a member of the union, rather that e.g. just as a pointer-to-struct with no context. – underscore_d May 31 '18 at 12:53

I suspect it means that the access to these common parts is permitted not only through the union type, but outside of the union. That is, suppose we have this:

union u {
  struct s1 m1;
  struct s2 m2;

Now suppose that in some function we have a struct s1 *p1 pointer which we know was lifted from the m1 member of such a union. We can cast this to a struct s2 * pointer and still access the members which are in common with struct s1. But somewhere in the scope, a declaration of union u has to be visible. And it has to be the complete declaration, which informs the compiler that the members are struct s1 and struct s2.

The likely intent is that if there is such a type in scope, then the compiler has knowledge that struct s1 and struct s2 are aliased, and so an access through a struct s1 * pointer is suspected of really accessing a struct s2 or vice versa.

In the absence of any visible union type which joins those types this way, there is no such knowledge; strict aliasing can be applied.

Since the wording is absent from C++, then to take advantage of the "common initial members relaxation" rule in that language, you have to route the accesses through the union type, as is commonly done anyway:

union u *ptr_any;
// ...
ptr_any->m1.common_initial_member = 42;
fun(ptr_any->m2.common_initial_member);  // pass 42 to fun
  • 3
    @underscore_d The suspicion had to be right because in what circumstance would we be accessing the member of a union, such that the (complete) declaration of the union is not in scope? The only way that is possible is that we obtain a pointer to that member and pass it out of scope. And that situation is not being ruled out: it is just being made subject to the union type still being in scope. Which must mean that the intent is that the union type informs the translator that the structs are involved in a union (so watch out: pointers to those struct types may be to union members). – Kaz Jan 6 '16 at 21:07
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    @underscore_d The thing is, that it's not actually an allowance but a restriction! From the perspective of the programmer, it's an allowance. But the standard is a set of requirements for implementors (many of which are given in terms of program behavior). The C standard is tighter: it requires implementors to be careful in their optimizations and support that usage. If that code is ported to C++, it has undefined behavior. Valid C that is undefined C++, though not diagnosed in C++, doesn't bode well for C++. Nobody wants new UB concerns when converting C to C++! – Kaz Jan 6 '16 at 21:41
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    Even in C89 mode, gcc no longer recognizes the common initial sequence rule for union members accessed through pointers of their individual types, even when the object in question is a union and the code using the union is in the same translation unit as the code acting upon the members; I see no way in which such compiler behavior can be deemed legitimate, since nothing in C89 would forbid such usage. – supercat Apr 19 '16 at 22:37
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    @underscore_d: The Standard's intent is clear, whether compiler writers like it or not. In C89, code which received from another translation unit pointers to two structure types that shared a CIS and might be part of a union in that other translation unit had to regard accesses to the CIS of one as a potential access to the CIS of either. From a practical standpoint, mainstream compilers prior to C99 unanimously (do you know of any exceptions?) regarded the CIS rule as extending to type-punned pointer rather than just unions, since that made the rule more useful and... – supercat Apr 20 '16 at 14:31
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    ...there was no benefit to interpreting it more narrowly. Nonetheless, the authors of C99 ignored that and viewed the rule as only applying to accesses through unions, but recognized that there had to be a way to tell the compiler that the CIS of two structure types could alias. Rather than invent a new syntax, they use the definition of a union containing both structures as a means of providing such notice. A program which passed pointers to members of a union defined in one translation unit to another unit where they would be used in such a fashion as to cause aliasing in the CIS... – supercat Apr 20 '16 at 14:36

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