9

I'm reading paragraph 7 of 6.5 in ISO/IEC 9899:TC2.

It condones lvalue access to an object through:

an aggregate or union type that includes one of the aforementioned types among its members (including, recursively, a member of a subaggregate or contained union),

Please refer to the document for what 'aforementioned' types are but they certainly include the effective type of the object.

It is in a section noted as:

The intent of this list is to specify those circumstances in which an object may or may not be aliased.

I read this as saying (for example) that the following is well defined:

#include <stdlib.h>
#include <stdio.h>

typedef struct {
    unsigned int x;
} s;

int main(void){
    unsigned int array[3] = {73,74,75};

   s* sp=(s*)&array; 

   sp->x=80;

   printf("%d\n",array[0]);

   return EXIT_SUCCESS;
}

This program should output 80.

I'm not advocating this as a good (or very useful) idea and concede I'm in part interpreting it that way because I can't think what else that means and can't believe it's a meaningless sentence!

That said, I can't see a very good reason to forbid it. What we do know is that the alignment and memory contents at that location are compatible with sp->x so why not?

It seems to go so far as to say if I add (say) a double y; to the end of the struct I can still access array[0] through sp->x in this way.

However even if the array is larger than sizeof(s) any attempt to access sp->y is 'all bets off' undefined behaviour.

Might I politely ask for people to say what that sentence condones rather than go into a flat spin shouting 'strict aliasing UB strict aliasing UB' as seems to be all too often the way of these things.

  • 3
    Breaking the strict aliasing rules can cause heavily optimizing compilers to generate code that doesn't do what you intend. I've seen reads/writes get re-ordered (through pointers it thought couldn't possibly point to the same object, but did), causing assignments to seemingly get "missed". – Jonathon Reinhart Jan 12 '15 at 19:06
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    Have you read and digested What is the strict aliasing rule? and the links pointed at from there? Do they help? – Jonathan Leffler Jan 12 '15 at 20:34
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    Note, since there is a deleted answer that mentions gcc and -fstrict-aliasing. The gcc documents says that that all levels have various degrees of false positives and negaties and so can not really be used as a reliable indication that the code does/does not violate strict aliasing. The checks fails on many trivial examples. – Shafik Yaghmour Jan 12 '15 at 22:09
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    Reading the various pages and posts on this, there seems to be a common misconception that if a X * and a Y * (incompatible) point to overlapping memory locations then they can't both be used to access any sub-object. However it seems to me to be very clear from the wording chosen by the standards that if X and Y both contain a member of the same type, then it is not an aliasing violation to access that member via X and via Y. – M.M Jan 12 '15 at 23:33
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    I was originally very skeptical about that code could be conforming code but apparently it is although seemingly unintentianlly. I learned something new from this question and it turns out this was indeed an excellent question. cc @JonathonReinhart – Shafik Yaghmour Jan 13 '15 at 3:34
7

The answer to this question is covered in proposal: Fixing the rules for type-based aliasing which we will see, unfortunately was not resolved in 2010 when the proposal was made which is covered in Hedquist, Bativa, November 2010 minutes . Therefore C11 does not contain a resolution to N1520, so this is an open issue:

There does not seem to be any way that this matter will be resolved at this meeting. Each thread of proposed approaches leads to more questions. 1 1:48 am, Thurs, Nov 4, 2010.

ACTION – Clark do more work in

N1520 opens saying (emphasis mine going forward):

Richard Hansen pointed out a problem in the type-based aliasing rules, as follows:

My question concerns the phrasing of bullet 5 of 6.5p7 (aliasing as it applies to unions/aggregates). Unless my understanding of effective type is incorrect, it seems like the union/aggregate condition should apply to the effective type, not the lvalue type.

Here are some more details:

Take the following code snippet as an example:

union {int a; double b;} u;
u.a = 5;

From my understanding of the definition of effective type (6.5p6), the effective type of the object at location &u is union {int a; double b;}. The type of the lvalue expression that is accessing the object at &u (in the second line) is int.

From my understanding of the definition of compatible type (6.2.7), int is not compatible with union {int a; double b;}, so bullets 1 and 2 of 6.5p7 do not apply. int is not the signed or unsigned type of the union type, so bullets 3 and 4 do not apply. int is not a character type, so bullet 6 does not apply.

That leaves bullet 5. However, int is not an aggregate or union type, so that bullet also does not apply. That means that the above code violates the aliasing rule, which it obviously should not.

I believe that bullet 5 should be rephrased to indicate that if the effective type (not the lvalue type) is an aggregate or union type that contains a member with type compatible with the lvalue type, then the object may be accessed.

Effectively, what he points out is that the rules are asymmetrical with respect to struct/union membership. I have been aware of this situation, and considered it a (non-urgent) problem, for quite some time. A series of examples will better illustrate the problem. (These examples were originally presented at the Santa Cruz meeting.)

In my experience with questions about whether aliasing is valid based on type constraints, the question is invariably phrased in terms of loop invariance. Such examples bring the problem into extremely sharp focus.

And the relevant example that applies to this situation would be 3 which is as follows:

struct S { int a, b; };
void f3(int *pi, struct S *ps1, struct S const *ps2)
{
  for (*pi = 0; *pi < 10; ++*pi) {
      *ps1++ = *ps2;
  }
}

The question here is whether the object *ps2 may be accessed (and especially modified) by assigning to the lvalue *pi — and if so, whether the standard actually says so. It could be argued that this is not covered by the fifth bullet of 6.5p7, since *pi does not have aggregate type at all.

Perhaps the intention is that the question should be turned around: is it allowed to access the value of the object *pi by the lvalue *ps2. Obviously, this case would be covered by the fifth bullet.

All I can say about this interpretation is that it never occurred to me as a possibility until the Santa Cruz meeting, even though I've thought about these rules in considerable depth over the course of many years. Even if this case might be considered to be covered by the existing wording, I'd suggest that it might be worth looking for a less opaque formulation.

The following discussion and proposed solutions are very long and hard to summarize but seems to end with a removal of the aforementioned bullet five and resolve the issue with adjustments to other parts of 6.5. But as noted above this issues involved were not resolvable and I don't see a follow-up proposal.

So it would seem as it standard the wording does seem to permit the scenario the OP demonstrates although my understanding is that this was unintentional and therefore I would avoid it and it could potentially change in later standards to be non-conforming.

  • Massive thanks Shafik. Part of that debate is pointing out a failure to cover the behaviour of unions in a section annotated as intended to say what aliasing is and is not conformant. I think it might be intended as symmetry. You can carve out pointers to members such as &(s.a). So why not stick a structure over compatible members? They are (logically) aligned and contain compatible bit patterns. Why should a low-level language such as C forbid such access? I still think that's what the author of that paragraph meant. I wonder who submitted it. – Persixty Jan 13 '15 at 7:58
  • PS: Totally agree it's not a recommended technique if only because it's vague, clearly little known and even less understood! I can imagine some process where a clever I/O function 'builds' a structure to a recipe based on types and offsets and then hands them back to the calling program. You would need to rely on this idea that structs can be treated as parts (and this says built up of parts) for such a scheme to be compliant. I do think the fact that I've only half implemented the structure (if you add a double y;) may be unintentional. It doesn't seem to have many legitimate uses. – Persixty Jan 13 '15 at 8:06
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    This answer (especially Example 3) really does talk about aliasing an int via a struct type that has int as member. However OP's code only aliases uint as uint. So I think OP's question remains unanswered. (sp->x clearly does not access all of *sp) – M.M Jan 13 '15 at 8:54
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    @m.m bullet five requires includes one of the aforementioned types among itsmembers which applies in the OPs code and is the case example 3 covers and I don't see anything in the proposal that prevents it from applying to this case. – Shafik Yaghmour Jan 13 '15 at 15:01
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    @DanAllen yes, optimization is a key issue, even if the language supports the code it is unclear to me whether the various compiler implementations do with such code. Simple examples don't show any optimization going on but I would not count on it. – Shafik Yaghmour Jan 13 '15 at 18:21
0

I think this text does not apply:

an aggregate or union type that includes one of the aforementioned types among its members (including, recursively, a member of a subaggregate or contained union),

sp->x has type unsigned int which is not an aggregate or union type.

In your code there is no strict aliasing violation: it is OK to read unsigned int as unsigned int.

The struct might have different alignment requirements to the array but other than that there is no problem.

Accessing via "an aggregate or union type" would be:

s t = *sp;
  • @JonathanLeffler It could be argued that sp->x means (*sp).x and therefore it is accessing through an aggregate or union type first, and then narrowing the access to only access x ... but in either case it is not a strict aliasing violation – M.M Jan 12 '15 at 22:17
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    c doesn't define that s pointer can even represent a char pointer. It is perfectly valid to have: sizeof(s*) == 2 and sizeof(unsigned int*) == 4 and/or different alignment between the two. – this Jan 12 '15 at 22:32
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    If the resulting pointer is not correctly aligned68)for the referenced type, the behavior is undefined. In the case the alignment is different you have ub; this could happen if sizes were different or not. – this Jan 12 '15 at 22:36
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    @MattMcNabb That is the problem, you are misreading the standard. This example shows cleary why stackoverflow.com/questions/98650/… and it even uses the same struct setup. – this Jan 12 '15 at 22:44
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    It is an aggregate type (s) that includes on of the aforementioned types (unsigned int). That sentence can't be read to say that the member has to be an aggregate type. It (I think) clear that if the member is an aggregate type then the rule applies recursively. I could have struct{ struct { struct { unsigned int x; } } } and still be OK but I'm definitely not obliged to engage in such nesting. – Persixty Jan 12 '15 at 23:15
0

I confess that the idea that I can lay a struct over a locally defined array in this way is frankly exotic. I still maintain that C99 and all subsequent standards permit it. If fact it's very arguable that members being objects in themselves the first bullet point in 6.7.5 allows it:

a type compatible with the effective type of the object

I think that's M.M's point.

Looking at the problem the other way, let's notice that it's absolutely legitimate (in a strictly conforming environment) to alias the member sp->x as an object in it's own right.

In the context of the code in my OP consider a function with prototype void doit(int* ip,s* sp); the following call is expected to behave logically:

doit(&(sp->x),sp);

NB: Program logic may (of course) may not behave as desired. For example if doit increments sp->x until it exceeds *ip then there's a problem! However what is not allowed in a conformant compiler is for the outcome to be corrupted by artifacts due to the optimizer ignoring aliasing potential.

I maintain that C would be all the weaker if the language required me to code:

int temp=sp->x;
doit(&temp,sp);
sp->x=temp;

Imagine all the cases where any call to any function has to be policed for the potential aliasing access to any part of the structures being passed. Such a language would probably be unusable.

Obviously a hard optimizing (i.e. non-compliant) compiler might make a complete hash of doit() if it doesn't recognize that ip might be an alias of member in the middle of sp. That's irrelevant to this discussion.

To set out when a compiler can (and cannot) make such assumptions is understood as the reason why the standard needs to set very precise parameters around aliasing. That is to give the optimizer some conditions to dis-count. In a low level language such as 'C' it could be reasonable (even desirable) to say that a suitably aligned pointer to an accessible valid bit pattern can be used to access to a value.

It is absolutely established that sp->x in my OP is pointing to a properly aligned location holding a valid unsigned int.

The intelligent concerns are whether the compiler/optimizer agree that's then a legitimate way to access that location or ignorable as undefined behavior.

As the doit() example shows it's absolutely established that a structure can be broken down and treated as individual objects which merely happen to have a special relationship.

This question appears to be about the circumstances when a set of members that happen to have that special relationship can have a structure 'laid over them'.

I think most people will agree that the program at the bottom of this answer performs valid, worthwhile functionality that if associated with some I/O library could 'abstract' a great deal of the work required to read and write structures. You might think there's a better way of doing it, but I'm not expecting many people to think it's not an unreasonable approach.

It operates by exactly that means - it builds a structure member by member then accesses it through that structure.

I suspect some of the people who object to the code in the OP are more relaxed about this. Firstly, it operates on memory allocated from the free-store as 'un-typed' universally aligned storage. Secondly, it builds a whole structure. In the OP I'm pointing the rules (at least appear to permit) that you can line up bits of a structure and so long as you only de-reference those bits everything is OK.

I somewhat share that attitude. I think the OP is slightly perverse and language stretching in a poorly written corner of the standard. Not something to put your shirt on.

However, I absolutely think it would be a mistake to forbid the techniques below as they rule out a logically very valid technique that recognizes structures can be built up from objects just as much as broken down into them.

However I will say that something like this is the only thing I could come up with where this sort of approach seems worthwhile. But on the other hand if you can't pull data apart AND/OR put it together then you quickly start to break the notion at C structures are POD - the possibly padded sum of their parts, nothing more, nothing less.

#include <stddef.h>
#include <stdlib.h>
#include <stdio.h>

typedef enum {
    is_int, is_double //NB:TODO: support more types but this is a toy.

} type_of;

//This function allocates and 'builds' an array based on a provided set of types, offsets and sizes.
//It's a stand-in for some function that (say) reads structures from a file and builds them according to a provided
//recipe. 
int buildarray(void**array,const type_of* types,const size_t* offsets,size_t mems,size_t sz,size_t count){
    const size_t asize=count*sz;
    char*const data=malloc(asize==0?1:asize);
    if(data==NULL){
        return 1;//Allocation failure.
    }
    int input=1;//Dummy...
    const char*end=data+asize;//One past end. Make const for safety!
    for(char*curr=data;curr<end;curr+=sz){
        for(size_t i=0;i<mems;++i){
            char*mem=curr+offsets[i];
            switch(types[i]){
                case is_int:
                    *((int*)mem)=input++;//Dummy...Populate from file...
                break;
                case is_double:
                    *((double*)mem)=((double)input)+((double)input)/10.0;//Dummy...Populate from file...
                    ++input;
                break;
                default:
                    free(data);//Better than returning an incomplete array. Should not leak even on error conditions.
                    return 2;//Invalid type!
            }
        }
    }
    if(array!=NULL){
        *array=data;
    }else{
        free(data);//Just for fun apparently...
    }
    return 0;
}

typedef struct {
    int a;
    int b;
    double c;
} S;

int main(void) {
    const type_of types[]={is_int,is_int,is_double};
    const size_t offsets[]={offsetof(S,a),offsetof(S,b),offsetof(S,c)};
    S* array=NULL;
    const size_t size=4;

    int err=buildarray((void **)&array,types,offsets,3,sizeof(S),size);
    if(err!=0){
        return EXIT_FAILURE;
    }
    for(size_t i=0;i<size;++i){
        printf("%zu: %d %d %f\n",i,array[i].a,array[i].b,array[i].c);
    }

    free(array);
    return EXIT_SUCCESS;
}

I think it's an interesting tension. C is intended to be that low level high level language and give the programmer almost direct access to machine operations and memory. That means the programmer can fulfill with the arbitrary demands of hardware devices and write highly efficient code. However if the programmer is given absolute control such as my point about an 'if it fits it's OK' approach to aliasing then the optimizer gets its game spoilt. So weirdly it's worth holding a little bit of performance back to return a dividend from the optimizer.

Section 6.5 of the C99 standard tries (and doesn't entirely succeed) to set that boundary out.

  • A compiler would have to be mind-numbingly obtuse not to allow access to a non-character structure member via sp->m, regardless of whether the Standard were to actually require it to do so. Further, the Rationale of the Standard explicitly recognizes that an obtuse compiler could be conforming and yet be of such low quality as to be useless. Putting those together, rather than trying to ponder how N1570 6.5p7 allows things it obviously should, I think it makes more sense to recognize that in some cases it doesn't, but decent compilers will behave as though it does anyway. – supercat Aug 9 '18 at 15:03

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