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Section § "Address and indirection operators" ¶3 says (relevant section only):

The unary & operator returns the address of its operand. ... If the operand is the result of a unary * operator, neither that operator nor the & operator is evaluated and the result is as if both were omitted, except that the constraints on the operators still apply and the result is not an lvalue. Similarly, if the operand is the result of a [] operator, neither the & operator nor the unary * that is implied by the [] is evaluated and the result is as if the & operator were removed and the [] operator were changed to a + operator. ...

This means that this:

#define NUM 10
int tmp[NUM];
int *i = tmp;
printf("%ti\n", (ptrdiff_t) (&*i - i) );
printf("%ti\n", (ptrdiff_t) (&i[NUM] - i) );

Should be perfectly legal, printing 0 and the NUM (10). The standard seems very clear that both of those cases are required to be optimized.

However, it doesn't seem to require the following to be optimized:

struct { int a; short b; } tmp, *s = tmp;
printf("%ti\n", (ptrdiff_t) (&s->b - s) );

This seems awfully inconsistent. I can see no reason that the above code shouldn't print the sizeof(int) plus (unlikely) padding (possibly 4).

Simplifying a &-> expression is going to be the same conceptually (IMHO) as &[], a simple address-plus-offset. It's even an offset that's going to be determinable at compile time, rather than potentially runtime with the [] operator.

Is there anything in the rationale about why this is so seemingly inconsistent?

share|improve this question
I've seen tons of hard C and C++ standards questions where I didn't know how to do anything but upvote, favorite and wait to read the answers. It feels weird to actually have written one. – Chris Lutz Feb 5 '11 at 6:53
interesting ... MSVC++ prints 4! – Abhi Feb 5 '11 at 7:19
@Abhi Rao - GCC (4.0) with -Wall -Wextra -Werror compiles and prints 4 with no complaint. – Chris Lutz Feb 5 '11 at 7:24
Now that we've eliminated the ill-formed null pointer examples, I don't really see a compelling use case for extending this feature to cover &->. Obviously the compiler can (and probably will) optimize out the actual dereferencing and taking the address, but I'm just not seeing a compelling example where some use of &-> is undefined under the current language rules but would be well defined under new rules that give &-> the same treatment as &*. – James McNellis Feb 5 '11 at 18:09
@James McNellis - You could make the offsetof hack word with a non-null pointer. And presumably if the standard required it to be optimized the ill-formed back would be more likely to work. – Chris Lutz Feb 5 '11 at 22:55
up vote 4 down vote accepted

In your example, &i[10] is actually not legal: it becomes i + 10, which becomes NULL + 10, and you can't perform arithmetic on a null pointer. (6.5.6/8 lists the conditions under which pointer arithmetic can be performed)

Anyway, this rule was added in C99; it was not present in C89. My understanding is that it was added in large part to make code like the following well-defined:

int* begin, * end;
int v[10];

begin = &v[0];
end = &v[10];

That last line is technically invalid in C89 (and in C++) but is allowed in C99 because of this rule. It was a relatively minor change that made a commonly used construct well-defined.

Because you can't perform arithmetic on a null pointer, your example (&s->b) would be invalid anyway.

As for why there is this "inconsistency," I can only guess. It's likely that no one thought to make it consistent or no one saw a compelling use case for this. It's possible that this was considered and ultimately rejected. There are no remarks about the &* reduction in the Rationale. You might be able to find some definitive information in the WG14 papers, but unfortunately they seem to be quite poorly organized, so trawling through them may be tedious.

share|improve this answer
I took null pointers out of the examples, since they were never really what I was concerned about. – Chris Lutz Feb 5 '11 at 7:33
I don't see how NULL comes into play at all here. In addition, for pointer arithmetic (as long as you don't evaluate the non-existing object) the element just after an array can be used. AFAIR, this is mentioned in several places of the standard. – Jens Gustedt Feb 5 '11 at 9:05
@Jens: The original examples in the question used the NULL pointer and no well-defined arithmetic may be performed on a null pointer. You can obtain a pointer to the one-past-the-end "element," but you cannot dereference it. For int v[10];, only in C99 is it legal to use &v[10] or &*(v + 10); in C++ and C90 such code formally yields undefined behavior. – James McNellis Feb 5 '11 at 18:04
I'm accepting this because "no one thought it was important" is probably the best answer I'll get without searching the rationale. And if I do want to search the rationale this answer has a nice link. – Chris Lutz Feb 6 '11 at 6:04

I think that the rule hasn't been added for optimization purpose (what does it bring that the as-if rule doesn't?) but to allow &t[sizeof(t)/sizeof(*t)] and &*(t+sizeof(t)/sizeof(*t)) which would be undefined behaviour without it (writing such things directly may seem silly, but add a layer or two of macros and it can make sense). I don't see a case where special casing &p->m would bring such benefit. Note that as James pointed out, &p[10] with p a null pointer is still undefined behaviour; &p->m with p a null pointer would similarly have stayed invalid (and I must admit that I don't see any use when p is the null pointer).

share|improve this answer
The obvious (IMHO) use when p = NULL is the hacky implementation of the offsetof macro, which relies on &((struct t *)0)->m working. It could, however, just as easily be changed to 1 (or a compiler-dependent valid pointer value like, say, the stack) instead of 0, and while it would probably be unlikely to give you good struct values it ought to give you the right offset value. – Chris Lutz Feb 5 '11 at 8:02
@Chris: an aeon ago, I had an early standard C compiler that defined offsetof() in terms off address 0 and then gave either core dumps or compilation errors (I forget which, now) when it was used. I ended up hacking the system header and used 1024 as an address instead of 0; that worked fine. It (1024) is sufficiently aligned not to give problems - unlike 1. – Jonathan Leffler Feb 6 '11 at 15:54
Except for character arrays, &t[sizeof(t)] reaches far beyond the end of the allocated object. – Jonathan Leffler Feb 6 '11 at 15:55
@Jonathan - Oh right, alignment exists. I feel rather silly now. – Chris Lutz Feb 7 '11 at 1:32
@JOnathan, Thanks, fixed in the post. – AProgrammer Feb 7 '11 at 9:07

I believe that the compiler can choose to pack in different ways, possibly adding padding between members of a struct to increase memory access speed. This means that you can't for sure say that b will always be an offset of 4 away. The single value does not have the same problem.

Also, the compiler may not know the layout of a struct in memory during the optimization phase, thus preventing any sort of optimization concerning struct member accesses and subsequent pointer casts.


I have another theory...

many times the compiler will optimize the abstract syntax tree just after lexical analysis and parsing. This means it will find things like operators that cancel out and expressions that evaluate to a constant and reduce those sections of the tree to one node. This also means that the information about structs is not available. later optimization passes that occur after some code generation may be able to take this into account because they have additional information, but for things like trimming the AST, that information is not yet there.

share|improve this answer
You can't be sure it'll always be an offset of 4, but for a struct to be useful you can be sure it'll be a constant offset. And I used an int followed by a short, so I doubt there's a compiler that needs to put padding in between them. – Chris Lutz Feb 5 '11 at 6:56
"Also, the compiler may not know the layout of a struct in memory during the optimization phase..." That seems like some pretty essential information for an optimizer to have. – Chris Lutz Feb 5 '11 at 6:58
i think it would also depend on how the compiler is written. The standard specifies rules for how it should work normally, but setting an optimization flag probably does do as you say. My guess is that the writers of the standard didn't want to impose too much optimization. – Scott M. Feb 5 '11 at 7:07
It seems like &s->b is less optimization than &i[x]. &s->b is the same as (typeof_b *)((char *)s)[offsetof(typeof_s, b)], and since offsetof is an integer constant expression (17.7 ¶3) this seems like it'd be even more likely to be optimizable. – Chris Lutz Feb 5 '11 at 7:19
I agree with Scott's answer that the single value doesn't have the same problem but for a different reason. Conceptually you're right, but you're thinking inhuman terms which doesn't always map to compiler functionality. To put it semantically you're trying to address an offset of nothing. – Dark Star1 Feb 5 '11 at 7:22

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