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Consider this program:

#include <stdio.h>

int main(void)
{
    unsigned int a;
    printf("%u %u\n", a^a, a-a);
    return 0;
}

Is its behaviour defined?

On the face of it, a is an uninitialised variable. So that points to undefined behaviour. But a^a and a-a are equal to 0 for all values of a, at least I think that is the case. Is it possible that there is some way to argue that the behaviour is well defined?

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I would expect this to be well-defined as the value of a is unknown but fixed and it should not change. The question is whether the compiler would allocate the space for a and subsequently read from the garbage sitting there. If not, then the behaviour is undefined. –  martin Aug 1 '14 at 6:35
    
Hmm so long as the variable isn't marked volatile then I would accept that as being defined behaviour. a ^= a, is exactly equivalent to a = 0 –  fileoffset Aug 1 '14 at 6:38
24  
@martin: It is not fixed. The value is allowed to change. This is a very practical consideration. A variable can be assigned to a CPU register, but while it is uninitialized (i.e. its effective value-lifetime hasn't begun yet), that same CPU register can be occupied by a different variable. The changes in that other variable will be seen as an "unstable" value of this uninitialized variable. This is something that is often observed in practice with uninitialized variables. –  AnT Aug 1 '14 at 6:39
    
@AndreyT this is a nice explanation –  martin Aug 1 '14 at 6:45
1  
Never mind, found it, my mistake: stackoverflow.com/questions/20300665/…, and it was in fact for C. –  Thomas Aug 1 '14 at 9:03

2 Answers 2

up vote 55 down vote accepted

In C11:

  • It's explicitly undefined according to 6.3.2.1/2 if a never has its address taken (quoted below)
  • It could be a trap representation (which causes UB when accessed). 6.2.6.1/5:

Certain object representations need not represent a value of the object type.

Unsigned ints can have trap representations (e.g. if it has 15 precision bits and 1 parity bit, accessing a could cause a parity fault).

6.2.4/6 says that the initial value is indeterminate and the definition of that under 3.19.2 is either an unspecified value or a trap representation.

Further: in C11 6.3.2.1/2, as pointed out by Pascal Cuoq:

If the lvalue designates an object of automatic storage duration that could have been declared with the register storage class (never had its address taken), and that object is uninitialized (not declared with an initializer and no assignment to it has been performed prior to use), the behavior is undefined.

This doesn't have the exception for character types, so this clause appears to supersede the preceding discussion; accessing x is immediately undefined even if no trap representations exist. This clause was added to C11 to support Itanium CPUs which do actually have a trap state for registers.


Systems without trap representations: But what if we throw in &x; so that that 6.3.2.1/2's objection no longer applies, and we are on a system that is known to have no trap representations? Then the value is an unspecified value. The definition of unspecified value in 3.19.3 is a bit vague, however it is clarified by DR 451, which concludes:

  • An uninitialized value under the conditions described can appear to change its value.
  • Any operation performed on indeterminate values will have an indeterminate value as a result.
  • Library functions will exhibit undefined behavior when used on indeterminate values.
  • These answers are appropriate for all types that do not have trap representations.

Under this resolution, int a; &a; int b = a - a; results in b having indeterminate value still.

Note that if the indeterminate value is not passed to a library function, we are still in the realm of unspecified behaviour (not undefined behaviour). The results may be weird, e.g. if ( j != j ) foo(); could call foo, but the demons must remain ensconced in the nasal cavity.

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Supposing that we knew there were no trap values, could we argue defined behaviour then? –  David Heffernan Aug 1 '14 at 6:40
11  
@DavidHeffernan You might as well treat access to indeterminate data as UB, because your compiler might, too, even if there are no trap values. Please see blog.frama-c.com/index.php?post/2013/03/13/… –  Pascal Cuoq Aug 1 '14 at 6:48
    
@Pascal I get that now. That's the final para of Andrey's answer. –  David Heffernan Aug 1 '14 at 6:51
    
@DavidHeffernan The examples go as far as 2 * j being odd, which is slightly worse than even the picture in Andrey's answer, but you get the idea. –  Pascal Cuoq Aug 1 '14 at 6:53

Yes, it is undefined behavior.

Firstly, any uninitialized variable can have "broken" (aka "trap") representation. Even a single attempt to access that representation triggers undefined behavior. Moreover, even objects of non-trapping types (like unsigned char) can still acquire special platform-dependent states (like NaT - Not-A-Thing - on Itanium) that might appear as a manifestation of their "indeterminate value".

Secondly, an uninitialized variable is not guaranteed to have a stable value. Two sequential accesses to the same uninitialized variable can read completely different values, which is why, even if both accesses in a - a are "successful" (not trapping), it is still not guaranteed that a - a will evaluate to zero.

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Have you got a citation for that final paragraph? If that is so, then we needn't even consider traps. –  David Heffernan Aug 1 '14 at 6:41
1  
@Matt McNabb: Well, this might be an issue that was resolved differently through different vesrions of the language spec. But the resolution for the DR#260 (open-std.org/jtc1/sc22/wg14/www/docs/dr_260.htm) states it clearly an explicitly that variables with indeterminate values can change arbitrarily "by themselves". –  AnT Aug 1 '14 at 6:57
3  
@Matt McNabb: DR#451 reasserted essentially the same decisions from DR#260 in both Oct 2013 and Apr 2014 open-std.org/Jtc1/sc22/WG14/www/docs/dr_451.htm . The commitree response for DR#451 explicitly states "This viewpoint reaffirms the C99 DR260 position" –  AnT Aug 1 '14 at 7:03
1  
@hyde The closest to a trap representation you may have at hand is signaling NaNs. en.wikipedia.org/wiki/NaN#Signaling_NaN Otherwise you need to get a computer with explicit parity bits, a sign-magnitude computer where -0 is considered a trap value, or something equally exotic. –  Pascal Cuoq Aug 1 '14 at 7:24
1  
@chux: No. There is nothing that restricts undefined behavior to "does what you think, but if not, traps". Literally any behavior is permitted. –  Ben Voigt Aug 1 '14 at 22:53

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