void swap(int* a, int* b)
    if (a != b){
        *a = *a ^ *b;
        *b = *a ^ *b;
        *a = *a ^ *b;

int main()
    int a = 0;
    int b = 1;
    swap(&a, &b); // after this b is 0 and a is 1
    return a > b ? 0 : a / b;

swap is an attempt to fool the compiler into not optimising out the program.

Is the behaviour of this program defined? a / b is never reachable, but if it was then you'd get a division by zero.

  • 4
    My understanding of UB is that it requires that a path that would unavoidably lead to an expression containing UB be reached. That is, as long as there is a chance that the expression with UB isn't reached, there is no UB. Though I can't find a source. Otherwise, common strategies such as checking for nullptr before calling a member function would be UB. Jan 11, 2018 at 15:10
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    @FrançoisAndrieux I would say the UB is when and only when a path to the expression is taken.
    – Eugene Sh.
    Jan 11, 2018 at 15:12
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    @You: That's on the C++ tag. I asked this on the C tag as the rules are generally simpler in C.
    – Bathsheba
    Jan 11, 2018 at 15:12
  • 2
    @You That's different. That question is asking rather introducing UB into a branch is enough to force the compiler to assume the branch is unreachable. Jan 11, 2018 at 15:12
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    @You That C may or may not have the same definition of UB as C++ is part of the answer, I should think. C and C++ are separate languages, and they're diverging more as the years pass, from what I understand. Nothing says they must have the same behavior, so I don't think closing as a duplicate of a C++ question is appropriate.
    – jpmc26
    Jan 11, 2018 at 23:48

3 Answers 3


It is not necessary to base a position on this question on the usefulness of any given code construct or practice, nor on anything written about C++, whether in its standard or in another SO answer, no matter how similar C++'s definitions may be. The key thing to consider is C's definition of undefined behavior:

behavior, upon use of a nonportable or erroneous program construct or of erroneous data, for which this International Standard imposes no requirements

(C2011, 3.4.3/1; emphasis added)

Thus, undefined behavior is triggered temporally ("upon use" of a construct or data), not by mere presence.* It is convenient that this is consistent for undefined behavior arising from data and that arising from program constructs; the standard need not have been consistent there. And as another answer describes, this "upon use" definition is a good design choice, as it allows programs to avoid executing undefined behaviors associated with erroneous data.

On the other hand, if a program does execute undefined behavior then it follows from the standard's definition that the whole behavior of the program is undefined. This consequent undefinedness is a more general kind arising from the fact that the UB associated directly with the erroneous data or construct could, in principle, include altering the behavior of other parts of the program, even retroactively (or apparently so). There are of course extra-lingual limitations on what could happen -- so no, nasal demons will not actually be making any appearances -- but those are not necessarily as strong as one might suppose.

* Caveat: some program constructs are used at translation time. These produce UB in program translation, with the result that every execution of the program has wholly-undefined behavior. For a somewhat stupid example, if your program source does not end with an unescaped newline then the program's behavior is completely undefined (see C2011,, point 2).

  • Your citation does not convince me. Use of a nonportable program construct could be that the developer added it to the program, and thus used the construct, even if it's never executed. The term use is unclear. Is there a wordlist in the standard? Jan 12, 2018 at 3:54
  • This is an excellent answer, covering not only the strict definition of undefined behavior according to the standard, but also the nuances involved in interpreting its meaning and consequences.
    – alecov
    Jan 12, 2018 at 4:52
  • @FilipHaglund: Aside from the citation, if you think about it, the alternative is completely nonsensical, at least in the given example of division by zero; If the mere presence of a construct that is undefined behavior would lead to undefined behaviour even when unreachable, you could not use the division operator at all - any attempt at checking for zero would be moot if unreachability wouldn't prevent the undefined behaviour. Jan 12, 2018 at 5:25
  • @Aleksi good point, now I am convinced :) Jan 12, 2018 at 11:07

The behavior of an expression that is not evaluated is irrelevant to the behavior of a program. Behavior that would be undefined if the expression were evaluated has no bearing on the behavior of the program.

If it did, then this code would be useless:

if (p != NULL)
    …; // Use pointer p.

(Your XORs could have undefined behavior, as they may produce a trap representation. You can defeat optimization for academic examples like this by declaring an object to be volatile. If an object is volatile, the C implementation cannot know whether its value may change due to external means, so each use of the object requires the implementation to read its value.)

  • 5
    Beware that it's not strictly necessary that an expression with UB be reached to cause UB if it can be proven that it would eventually be reached. Jan 11, 2018 at 15:14
  • 1
    @FrançoisAndrieux This is not clear what it means. C programs are usually deterministic. If a path can be reached in a specific run (with determined input/time and/or rand output), it will be reached.
    – Eugene Sh.
    Jan 11, 2018 at 15:23
  • 3
    @EugeneSh. I meant that a program has UB if it can be proven that a path leads to an expression with UB under all conditions. That is, if at a given point it can be proven that all path lead to UB, the program is already UB at that point. A compiler may make that determination and act accordingly, altering behavior before the actual UB expression is reached. Jan 11, 2018 at 15:28
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    @Bathsheba: Go ahead and edit the question if you think that would improve it. And edit the answer some if it needs to match. I can review it later. Gotta go now. Jan 11, 2018 at 15:35
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    @ruakh In that case, the UB expression is not unreachable The error reporting branch does not return or otherwise prevent control from continuing through the function so control is assumed to eventually reach the UB. Rather the example is saying that the branch could be removed because during optimization because the only case when it could be taken is also a case where UB is certain to be reached. Jan 12, 2018 at 11:58

In general, code which would invoke Undefined Behavior if executed must not have any effect if it is not executed. There are, however, a few cases where real-world implementations may behave in contrary fashion and refuse to generate code which, while not a constraint violation, could not possibly execute in defined behavior.

extern struct foo z;

int main(int argc, char **argv)
    if (argc > 2) z;
    return 0;

By my reading of the Standard, it explicitly characterizes lvalue conversions on incomplete types as invoking Undefined Behavior (among other things, it's unclear what an implementation could generate code for such a thing), so the Standard would impose no requirements upon behavior if argc is 3 or more. I can't identify any constraint in the Standard that the above code would violate, however, nor any reason behavior should not be fully defined if argc is 2 or less. Nonetheless, many compilers including gcc and clang reject the above code entirely.

  • At if (argc > 2) z;, the compiler is supposed to evaluate z, but z is a variable of incomplete type, so it cannot be evaluated. The compilers are right to reject the code.\ Jan 11, 2018 at 17:25
  • @JonathanLeffler: The Standard describes the evaluation of an incomplete type as being UB rather than a constraint violation. What it should do IMHO is have a category for constructs which compilers may accept or reject at their leisure without regard for whether they are executed, but must not interfere with operation unless either (1) they cause the program to be rejected, or (2) they are executed.
    – supercat
    Jan 11, 2018 at 18:40
  • OK; so the compilers are correct to decide that they're going to reject your attempt to invoke UB . because they have no idea what you really mean and they can do what they like when it is UB. I don't see that as a compiler problem; it is bad C code. Jan 11, 2018 at 18:43
  • @JonathanLeffler: Nothing I can see in the Standard would indicate that the aforementioned program would not have defined behavior if invoked with argc <= 2. While I would agree that the Standard probably shouldn't imply that quality compilers must accept such a program, the only justification I can see for an implementation doing otherwise would be declaring that such a program exceeds some implementation limit--a loophole that would justify doing almost anything with almost any program.
    – supercat
    Jan 11, 2018 at 18:56
  • We'd best cease this discussion here. If you wish, we can remove all the comments. Jan 11, 2018 at 18:57

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