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The equality operators have the semantic restrictions of relational operators on pointers:

The == (equal to) and the != (not equal to) operators have the same semantic restrictions, conversions, and result type as the relational operators except for their lower precedence and truth-value result. [C++03 §5.10p2]

And the relational operators have a restriction on comparing pointers:

If two pointers p and q of the same type point to different objects that are not members of the same object or elements of the same array or to different functions, or if only one of them is null, the results of p<q, p>q, p<=q, and p>=q are unspecified. [§5.9p2]

Is this a semantic restriction which is "inherited" by equality operators?

Specifically, given:

int a[42];
int b[42];

It is clear that (a + 3) < (b + 3) is unspecified, but is (a + 3) == (b + 3) also unspecified?

share|improve this question
Interesting question. If it was so, what about all the self-assignment tests if (this != &other) – UncleBens Feb 5 '11 at 21:31
Except for the opaque phrasing, it seems really quite simple: The standard fully specifies under which circumstances two pointers compare not-equal. Which pointer value (address) of two unrelated objects is larger however, is simply (and - IMHO - rather obviously) unspecified. – Martin Ba Feb 5 '11 at 21:44
@Martin: What about a segmented architecture with near pointers having same offset, but for different segments? I don't think you'd want equality to be fully specified in this case, and the standard requires this comparison case to be well-formed (must compile, execute, etc.), near as I can tell. – Fred Nurk Feb 5 '11 at 21:50
the standard does require meaningful results, even in that case -- i.e., == must only be true if both of them are null pointers, or else refer to the same object (and the converse for !=, of course). – Jerry Coffin Feb 5 '11 at 21:58
up vote 13 down vote accepted

The semantics for op== and op!= explicitly say that the mapping is except for their truth-value result. So you need to look what is defined for their truth value result. If they say that the result is unspecified, then it is unspecified. If they define specific rules, then it is not. It says in particular

Two pointers of the same type compare equal if and only if they are both null, both point to the same function, or both represent the same address

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I was not reading it as the unspecified-ness of the result being included in "except for their truth-value result", since that would seem to negate "have the same semantic restrictions". I'm not sure this answer is the best way to interpret or not, but it would resolve this question. – Fred Nurk Feb 5 '11 at 21:39
+1 : I totally agree about the interpretation of except for their truth-value result. It is horrible standardese though :-) – Martin Ba Feb 5 '11 at 21:39

The simple answer is that the result from equality operators (== and !=) are defined [Edit: i.e., specified], but from the ordering operators (<, <=, >, >=) are not [edit: i.e., they are unspecified].

Despite that, however, the comparison templates in the standard library (std::less, std::greater, std::less_equal and std::greater_equal) do all yield a meaningful result, even when/if the built-in operators do not. In particular, they are required to yield a total ordering. As such, you can get ordering if you want it, just not with the built-in comparison operators.

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The relational operators are defined, but unspecified in the given case. None of the comparison operators (when used on pointers) are undefined. I'm asking about == and not <, and std::equal_to says it uses == without being included in the special allowance for std::less, etc. – Fred Nurk Feb 5 '11 at 21:53
@Fred -- the operators are defined, but the results are not. I guess I could try to re-word that to be a bit more clear, but (IMO) what I've said is already easier to understand than the wording in the standard. – Jerry Coffin Feb 5 '11 at 21:56
The results are unspecified, which is distinctly defined differently from undefined (as in undefined behavior). A terminological nitpick, perhaps, but important since UB has severe implications; and one which I found surprising, since I had also thought they were UB. – Fred Nurk Feb 5 '11 at 21:58
At least IMO, saying a result is not defined is different from saying that the code has undefined behavior, but I've done a bit of editing to ensure against that misunderstanding. – Jerry Coffin Feb 5 '11 at 22:02
I think you are using "a result is not defined" to mean exactly what the standard means with "unspecified", which, in contrast to "implementation-defined", doesn't require documentation and thus doesn't require consistency. (I base the lack of consistency on behavior that's undocumented can always include non-obvious and unspecified factors affecting it.) We both definitely agree it's different from undefined, but if you do mean what the standard does with "unspecified", then I think it's best to use that word when talking standardese. – Fred Nurk Feb 5 '11 at 23:20

Since there's confusion on conformance semantics, these are the rules for C++. C uses a completely different conformance model.

  1. Undefined behaviour is an oxymoronic term, it means the translator NOT your program, may do as it pleases. This generally means it can generate code which will also do anything it pleases (but that is a deduction). Where the Standard says behaviour is undefined the text is actually of no significance to the user in the sense that eliding this text will not change the requirements the Standard imposes on translators.

  2. Ill formed program means that unless otherwise specified the behaviour of the translator is rigidly defined: it is required to reject your program and issue a diagnostic message. The primary special case here is the One-Definition Rule, if you breach that your program is ill-formed but no diagnostic is required.

  3. Implementation defined imposes a requirement on the translator that it contain documentation specifying the behaviour explicitly. In this special case Undefined Behaviour can be the result but must be explicitly stated.

  4. Unspecified is a stupid term which means that the behaviour come from a set. In this sense well-defined is just a special case where the set of permitted behaviours contains only one element. Unspecified does not require documentation, so in some sense it also means the same as implementation defined without documentation.

In general, the C++ Standard is a not a Language Standard, it is a model for a language Standard. To generate an actual Standard you have to plug in various parameters. The easiest of these to recognize are the implementation defined limits.

There are a couple of silly conflicts in the Standard, for example, a legitimate translator can reject every apparently good C++ program on the basis that you are required to supply a main() function but the translator only supports identifiers of 1 character. This problem is resolve by the notion of QOI or Quality of Implementation. It basically says, who cares, no one is going to buy that compiler just because it is conforming.

Technically the unspecified nature of operator < when the pointers are to unrelated objects is probably intended to mean: you will get some kind of result which is either true or false but your program will not crash, however this is not the correct meaning of unspecified, so that is a Defect: unspecified imposed a burden on the Standards writers to document the set of allowed behaviours because if the set is open, then it is equivalent to undefined behaviour.

I actually proposed std::less as a solution to the problem that some data structures require keys to be totally ordered, but pointers are not totally ordered by operator <. On most machines using linear addressing less is the same as <, but the less operation on, say, an x86 processor is potentially more expensive.

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What term would you prefer to describe the situation where there is no guarantee as to the value an expression will produce, but code may nonetheless legitimately evaluate the expression if it is prepared for any value that may result? For example, suppose f(x), f(y), and f(z) should ideally all yield the same value, but at most one of x, y, or z may be corrupt. If operations on a corrupt value yield indeterminate result, one could (absent side-effects) safely say temp = f(x); return temp==f(y) ? temp : f(z); even if one couldn't determine whether x, y, or z was corrupt. – supercat Dec 11 '13 at 19:45
If invoking f() on a corrupt value were not guaranteed safe, then if one didn't save some other means of telling whether x, y, or z was corrupt one couldn't handle corruption. On the other hand, if the invocation is safe, then even though one wouldn't know when storing temp whether the value was good or not, one would nonetheless be able to determine that later. – supercat Dec 11 '13 at 19:48

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