# Is incrementing a null pointer well-defined?

There are lots of examples of undefined/unspecified behavior when doing pointer arithmetics - pointers have to point inside the same array (or one past the end), or inside the same object, restrictions on when you can do comparisons/operations based on the above, etc.

Is the following operation well-defined?

``````int* p = 0;
p++;
``````
• I'm curious as to why you think it wouldn't be... Apr 23, 2015 at 13:44
• @ddriver, Being undefined behaviour, it doesn't have to know. It can be assumed that you follow the rules and don't incur UB. Apr 23, 2015 at 14:47
• @ddriver, Well, imagine the implementation traps if you overflow past 0x1000. You have an array of 3 four-byte ints located at 0xFF0. `arr + 1` would be implemented as `0xFF0 + 1*4 = 0xFF4`. Similarly for `arr + 2` through `arr + 4`. Now imagine `arr + 5`. There's the trap from going past 0x1000, but that's okay since it's undefined behaviour. Placing the array any farther in memory would not be okay, lest `arr + 4` traps. Now imagine it's at 0x100. `arr + 5` is implemented as `0x100 + 5*4 = 0x114`. It's out of range, but no trap. This is also okay because it's undefined behaviour, but "works" Apr 23, 2015 at 14:59
• @ddriver Optimizing compilers are fond of assuming "UB never happens". So they're free to assume that your code that invokes UB is unreachable and proceed to destroy everything using that contradiction. Apr 23, 2015 at 15:27
• @ddriver If you think that UB can only make problems if it would make "sense" according to the used architecture, you're at least ten years behind on compilers. Example: x86 has 2s complement arithmetic, so `int overflows(int x) { return x + 1 < x;}` should always give you the right result, right? On modern gccs you have a good chance that the function will be optimized to `return false`.
– Voo
Apr 23, 2015 at 17:32

§5.2.6/1:

The value of the operand object is modified by adding `1` to it, unless the object is of type `bool` [..]

And additive expressions involving pointers are defined in §5.7/5:

If both the pointer operand and the result point to elements of the same array object, or one past the last element of the array object, the evaluation shall not produce an overflow; otherwise, the behavior is undefined.

• I'm curious how "array object" is defined in the standard. Is return value of `malloc` considered array object? Apr 23, 2015 at 14:05
• How do you guarantee that `1` has a corresponding pointer representation for mappings between pointers and integers are otherwise implementation-defined? Apr 23, 2015 at 14:13
• @Lingxi The first part of that quote says that you can convert it. The resulting value is impementation-defined, but the operations legality is guaranteed, isn't it? (Actually, it should've been sizeof(int), forgot to adjust that - still, converting from 1 to it should be valid.) Apr 23, 2015 at 14:16
• @Columbo: An implementation could legitimately specify that any integer value which it recognizes as never having been the result of a pointer-to-integer cast may yield a trap representation when converting to a pointer. Apr 23, 2015 at 15:17
• If hypothetically a call to `Foo *p = static_cast<Foo *>(malloc(0));` that resulted with `p` holding non-NULL pointer, then it would be UB to increment that `p` as well.
– jxh
Apr 23, 2015 at 16:48

There seems to be quite low understanding what "undefined behaviour" means.

In C, C++, and related languages like Objective-C, there are four kinds of behaviour: There is behaviour defined by the language standard. There is implementation defined behaviour, which means the language standard explicitely says that the implementation must define the behaviour. There is unspecified behaviour, where the language standard says that several behaviours are possible. And there is undefined behaviour, where the language standard doesn't say anything about the result. Because the language standard doesn't say anything about the result, anything at all can happen with undefined behaviour.

Some people here assume that "undefined behaviour" means "something bad happens". That's wrong. It means "anything can happen", and that includes "something bad can happen", not "something bad must happen". In practice it means "nothing bad happens when you test your program, but as soon as it is shipped to a customer, all hell breaks loose". Since anything can happen, the compiler can actually assume that there is no undefined behaviour in your code - because either it is true, or it is false, in which case anything can happen, which means whatever happens because of the compiler's wrong assumption is still correct.

Someone claimed that when p points to an array of 3 elements, and p + 4 is calculated, nothing bad will happen. Wrong. Here comes your optimising compiler. Say this is your code:

``````int f (int x)
{
int a [3], b [4];
int* p = (x == 0 ? &a [0] : &b [0]);
p + 4;
return x == 0 ? 0 : 1000000 / x;
}
``````

Evaluating p + 4 is undefined behaviour if p points to a [0], but not if it points to b [0]. The compiler is therefore allowed to assume that p points to b [0]. The compiler is therefore allowed to assume that x != 0, because x == 0 leads to undefined behaviour. The compiler is therefore allowed to remove the x == 0 check in the return statement and just return 1000000 / x. Which means your program crashes when you call f (0) instead of returning 0.

Another assumption made was that if you increment a null pointer and then decrement it again, the result is again a null pointer. Wrong again. Apart from the possibility that incrementing a null pointer might just crash on some hardware, what about this: Since incrementing a null pointer is undefined behavour, the compiler checks whether a pointer is null and only increments the pointer if it isn't a null pointer, so p + 1 is again a null pointer. And normally it would do the same for the decrementing, but being a clever compiler it notices that p + 1 is always undefined behaviour if the result was a null pointer, therefore it can be assumed that p + 1 isn't a null pointer, therefore the null pointer check can be ommitted. Which means (p + 1) - 1 is not a null pointer if p was a null pointer.

• This would seem to be the only answer on the page, that actually knows what "undefined behaviour" means. Apr 24, 2015 at 9:39
• This rant doesn't even attempt to address that thing up the top - ahhh - what's it called... oh yeah - the question, which is not "how might undefined behaviour manifest", but whether the code in the question has undefined behaviour or not. (In fairness, it does eventually reach a discussion that's premised on incrementing a null pointer being undefined without stating or justifying such.) This answer would be better moved to an appropriate question.... Apr 24, 2015 at 10:43

Operations on a pointer (like incrementing, adding, etc) are generally only valid if both the initial value of the pointer and the result point to elements of the same array (or to one past the last element). Otherwise the result is undefined. There are various clauses in the standard for the various operators saying this, including for incrementing and adding.

(There are a couple of exceptions like adding zero to NULL or subtracting zero from NULL being valid, but that doesn't apply here).

A NULL pointer does not point at anything, so incrementing it gives undefined behaviour (the "otherwise" clause applies).

• They can point to an object, and one byte past an object, too. Apr 23, 2015 at 13:56
• @Columbo: what are you refering to? Apr 23, 2015 at 14:25
• @Zaibis Probably the rule that a pointer to one element past the end of an array is valid i.e. that `a+3` is valid when you have a `int a[3]`, despite pointing to no valid element. But talking about "one byte" is a bit weird. Apr 23, 2015 at 15:24
• You are wrong about adding zero; no exception is made in additive operations when adding zero, and for an invalid pointer value it can cause UB. This is one reason why there are cases where `p[0]` is not strictly equivalent to `*p` (when the contents of that location is not actually used), see for instance this answer. Apr 24, 2015 at 7:20
• What you say is true for C, but is not true for C++, Marc. First sentence of C++98 - Section 5.7, para 8 says "If the value 0 is added to or subtracted from a pointer value, the result compares equal to the original pointer value." (I don't have more recent versions of the C++ standard at hand to check section numbers right now). There's an article by Andrew Koenig discussing why, drdobbs.com/cpp/why-does-c-allow-arithmetic-on-null-poin/… Apr 24, 2015 at 8:59

As said by Columbo it is UB. And from a language lawyer point of view this is the definitive answer.

However all C++ compiler implementations I know will give same result :

``````int *p = 0;
intptr_t ip = (intptr_t) p + 1;

cout << ip - sizeof(int) << endl;
``````

gives `0`, meaning that `p` has value 4 on a 32 bit implementation and 8 on a 64 bits one

Said differently :

``````int *p = 0;
intptr_t ip = (intptr_t) p; // well defined behaviour
ip += sizeof(int); // integer addition : well defined behaviour
int *p2 = (int *) ip;      // formally UB
p++;               // formally UB
assert ( p2 == p) ;  // works on all major implementation
``````
• I wouldn't trust a modern optimizing compiler with this. For example it's quite plausible that it decides that in `p2=p+1; if(p==nullptr){...}` the condition will never be fulfilled (since p==null would have resulted in UB on the first statement) and remove the whole `if` statement. Apr 23, 2015 at 15:31
• As I said in first line it is definitely UB. But I could not find an example of program, compiler and parameters to exhibit the problem you give. Apr 23, 2015 at 15:39
• @SergeBallesta: GCC, and even by default (that's why there is a `-fno-delete-null-pointer-checks` flag) Apr 23, 2015 at 17:05
• @MSalters I'm not sure if current compilers detect `p++` as UB, or if they only do this when you dereference the pointer. But no matter if they detect it now, it's only a small step from optimizing the dereference case step to "optimizing" this case as well. Apr 23, 2015 at 17:17
• @CodesInChaos: It would be far simpler to detect it at the lowest level. And the GCC case became known from breaking the linux kernel on the equivalent of `int p = foo->bar`. At the HW level, both are just pointer increments. One adds `sizeof(*p)` bytes, the other `offsetof(cFoo, bar)`. Apr 23, 2015 at 17:25

It turns out it's actually undefined. There are systems for which this is true

``````int *p = NULL;
if (*(int *)&p == 0xFFFF)
``````

Therefore, ++p would trip the undefined overflow rule (turns out that sizeof(int *) == 2)). Pointers aren't guaranteed to be unsigned integers so the unsigned wrap rule doesn't apply.

• It converts the value of p to an integer. The strange expression is required to prevent the compiler from generating the code to replace NULL with 0. The actual bitwise value is relevant here. Apr 23, 2015 at 23:31
• That is not incrementing NULL. It is reassigning the value of the pointer. Apr 24, 2015 at 10:45

From ISO IEC 14882-2011 §5.2.6:

The value of a postfix ++ expression is the value of its operand. [ Note: the value obtained is a copy of the original value —end note ] The operand shall be a modifiable lvalue. The type of the operand shall be an arithmetic type or a pointer to a complete object type.

Since a nullptr is a pointer to a complete object type. So I wouldn't see why this would be undefined behaviour.

As has been said before the same document also states in §5.2.6/1:

If both the pointer operand and the result point to elements of the same array object, or one past the last element of the array object, the evaluation shall not produce an overflow; otherwise, the behavior is undefined.

This expression seems a bit ambiguous. In my interpretation, the undefined part might very well be the evaluation of the object. And I think nobody would disagree with this being the case. However, pointer arithmetics seem to only require a complete object.

Of course postfix [] operators and subtractions or multiplications on pointer to array objects are only well defined, if they in fact point to the same array. Mostly important because one might be tempted to think that 2 arrays defined in succession in 1 object, can be iterated over like they were a single array.

So my conclusion would be that the operation is well defined, but evaluation would not be.

The C Standard requires that no object which is created via Standard-defined means can have an address which is equal to a null pointer. Implementations may allow for the existence of objects which are not created via Standard-defined means, however, and the Standard says nothing about whether such an object might have an address which (likely because of hardware design issues) is the same as a null pointer.

If an implementation documents the existence of a multi-byte object whose address would compare equal to null, then on that implementation saying `char *p = (char*)0;` would make `p` hold a pointer to the first byte of that object [which would compare equal to a null pointer], and `p++` would make it point to the second byte. Unless an implementation either documents the existence of such an object, however, or specifies that it will perform pointer arithmetic as though such an object exists, there is no reason to expect any particular behavior. Having implementation deliberately trap attempts to perform any kind of arithmetic on null pointers other than adding or subtracting zero or other null pointers can be a useful safety measure, and code that would increment null pointers for some intended useful purpose would be incompatible with it. Worse, some "clever" compilers may decide that they can omit null checks in cases on pointers that would get incremented even if they hold null, thus allowing all manner of havoc to ensue.

Back in the fun C days, if p was a pointer to something, p++ was effectively adding the size of p to the pointer value to make p point at the next something. If you set the pointer p to 0, then it stands to reason that p++ would still point it at the next thing by adding the size of p to it.

What's more, you could do things like add or subtract numbers from p to move it along through memory (p+4 would point at the 4th something past p.) These were good times that made sense. Depending on the compiler, you could go anywhere you wanted within your memory space. Programs ran fast, even on slow hardware because C just did what you told it to and crashed if you got too crazy/sloppy.

So the real answer is that setting a pointer to 0 is well-defined and incrementing a pointer is well-defined. Any other constraints are placed on you by compiler builders, os developers and hardware designers.

• Isn't it the other way round? C standard doesn't define it, but compiler vendors are free to define it for a particular platform.
– Kos
Apr 24, 2015 at 7:50
• I just remember what my old K&R said when it talked about pointers, that this is the way they were supposed to work. If compiler vendors made it not work intuitively then I'd probably not use that compiler unless my arm was twisted roughly. :-) Apr 24, 2015 at 8:11
• OTOH, you didn't get this level of optimisation from compilers back then. Tradeoffs, tradeoffs...
– Kos
Apr 24, 2015 at 8:59
• Question is about C++. "Real answer" is what the standard defines or does not define. Apr 24, 2015 at 9:09
• As I understand it, the definition of what's a pointer in C and what's a pointer in C++ is the same. There are no pointer arithmetic differences, in any case. Assigning a pointer to 0 is legal - your code may in fact use it to detect the end of a chain, for instance. And incrementing a pointer should take you to the next thing in an array, making no assumptions about the interpretation of what the pointer's value is. Optimisation be damned, if I write an algorithm to work a particular way using pointers to bounce around a list of objects, it had better not make legal code stop working. Apr 29, 2015 at 21:10

Given that you can increment any pointer of a well-defined size (so anything that isn't a void pointer), and the value of any pointer is just an address (there's no special handling for NULL pointers once they exist), I suppose there's no reason why an incremented null pointer wouldn't (uselessly) point to the 'one after NULL'est item.

Consider this:

``````// These functions are horrible, but they do return the 'next'
// and 'prev' items of an int array if you pass in a pointer to a cell.
int *get_next(int *p) { return p+1; }
int *get_prev(int *p) { return p-1; }

int *j = 0;

int *also_j = get_prev(get_next(j));
``````

also_j has had maths done to it, but it's equal to j so it's a null pointer.

Therefore, I would suggest that's it's well-defined, just useless.

(And the null pointer appearing to have the value zero when printfed is irrelevant. The value of the null pointer is platform dependent. The use of a zero in the language to initialise pointer variables is a language definition.)

• A good implementation should trap any attempt to add or subtract any integer from a null pointer at run-time (most of the harm from the "billion dollar mistake" stems from platforms' failures to do so). There are very few platforms where such behavior would ever be necessary, and in practice such behavior is almost always followed by a stray memory access. The only time in which implied arithmetic on a null pointer would be useful would be in cases which are entirely compile-time resolvable as the difference between two pointers which have constant displacements from a common base. Apr 23, 2015 at 15:14
• Your assumption that it's correct since it's intuitive or works on your system is wrong. C++ is governed by the language rules, which are described by the standard. Some rules are counter-intuitive, but the reasoning behind them is that it allows implementations to perform certain optimizations which otherwise wouldn't be possible. Apr 23, 2015 at 22:48
• @LuchianGrigore: There's also the problem that if incrementing a null pointer isn't undefined behaviour, then it must be defined somehow. Well, I wouldn't want to be responsible for defining what incrementing a null pointer does. Microprocessor Cat claims that the result is defined as "something that produces a null pointer if you decrement it". Apr 23, 2015 at 23:38
• I'd like to know why this answer was downvoted. Was the code specifically incorrect, or my conclusions? Apr 24, 2015 at 9:29
• Micro - your answer was about your ideas on how or what is sensible. (You may or may not be completely correct.) The question is completely unrelated to "what is sensible." It's simply a "language law" question. Apr 24, 2015 at 9:40