In C and C++, it is often useful to use a past-the-end pointer to write functions that can operate on arbitrarily large arrays. C++ gives a std::end overload to make this easier. In C, on the other hand, I've found it's not uncommon to see a macro defined and used like this:

#define ARRAYLEN(array) (sizeof(array)/sizeof(array[0]))

// ...

int a [42];
do_something (a, a + ARRAYLEN (a));

I've also seen a pointer arithmetic trick used to let such functions operate on single objects:

int b;
do_something (&b, &b + 1);

It occured to me that something similar could be done with arrays, since they are considered by C (and, I believe, C++) to be "complete objects." Given an array, we can derive a pointer to an array immediately after it, dereference that pointer, and use array-to-pointer conversion on the resulting reference to an array to get a past-the-end pointer for the original array:

#define END(array) (*(&array + 1))

// ...

int a [42];
do_something (a, END (a));

My question is this: In dereferencing a pointer to a non-existent array object, does this code exhibit undefined behaviour? I'm interested in what the most recent revisions of both C and C++ have to say about this code (not because I intend to use it, as there are better ways of achieving the same result, but because it's an interesting question).

  • 1
    I'm suprised this doesn't have an answer yet, but after doing a bunch of reading I think the consensus is that pointing one past the end of an array is a valid pointer that cannot be dereferenced. A common passage from the C standard that is quoted is 6.5.6/8. In C++ it is 5.7/5. If you're interested, here's a diff checker link.
    – user1508519
    Dec 14, 2013 at 1:59
  • @remyabel This seems to indicate that the code is not legal. For the purpose of pointer arithmetic, C (not sure about C++) considers a complete object to be equivalent to the sole element of an array of extent 1 (in this case, the array of type int[42] is the sole element of an array of type int[1][42]). 6.5.8 explicitly forbids dereferencing a past-the-end pointer (in an evaluated context), such as the pointer formed by &array + 1, which is being dereferenced. Dec 14, 2013 at 5:13
  • @StuartOlsen: But is array-to-pointer conversion (commonly called decay) an evaluated context? It doesn't use the value of the object, only its address.
    – Ben Voigt
    Dec 14, 2013 at 5:23
  • @BenVoigt I believe the evaluated context rule is referring to the indirection being evaluated (i.e., *ptr appears outside of a sizeof/alignof/_Alignof expression). "If the result points one past the last element of the array object, it shall not be used as the operand of a unary * operator that is evaluated" -, N1570 Dec 14, 2013 at 5:27
  • @StuartOlsen: Those undoubtedly are unevaluated contexts. But others might be. In C++, for example, binding a reference doesn't evaluate the object it is binding to. (Note at section 5.3.1 paragraph 1)
    – Ben Voigt
    Dec 14, 2013 at 5:29

3 Answers 3


I've used that in my own code, as (&arr)[1].

I'm quite sure it is safe. Array to pointer decay is not "lvalue-to-rvalue conversion", although it starts with an lvalue and ends with an rvalue.

  • Does either standard allow you to indirect through a pointer which does not point to an object (e.g., the pointer &arr + 1) if the resulting lvalue (reference) does not undergo lvalue-to-rvalue conversion? Both languages make reference to the "object" referred to by the pointer, which seems to imply that there must be an object of appropriate type at the location described by the pointer to dereference it. The best I can find is that C allows such an indirection to occur when immediately canceled by the address-of operator (e.g., &*NULL), which isn't quite what's happening here. Dec 14, 2013 at 5:05
  • @Stuart: The C++ Standard contains (4p8) a note to that effect, and makes the operand of the & address-of operator an example... but it's not limited to the & operator, it applies anywhere that lvalue-to-rvalue conversion does not appear. Also, the rule which makes access through an invalid pointer value undefined behavior is 4.1p2, and applies only to lvalue-to-rvalue conversion.
    – Ben Voigt
    Dec 14, 2013 at 5:14

It is undefined behaviour.

a is of type array of 42 int.

&a is of type pointer to array of 42 int. (Note this is not an array-to-pointer conversion)

&a + 1 is also of type pointer to array of 42 int

5.7p5 states:

When an expression that has integral type is added to or subtracted from a pointer, the result has the type of the pointer operand. If the pointer operand points to an element of an array object, and [...] otherwise, the behavior is undefined

The pointer does not point to an element of an array object. It points to an array object. So the "otherwise, the behaviour is undefined" is true. Behaviour is undefined.

  • At least in C++, this is incorrect. There's a rule that allows every object to be treated as an array of size 1.
    – Ben Voigt
    Dec 14, 2013 at 5:07
  • @BenVoigt: Standard reference? Dec 14, 2013 at 5:08
  • 5.7p4 "For the purposes of these operators, a pointer to a nonarray object behaves the same as a pointer to the first element of an array of length one with the type of the object as its element type."
    – Ben Voigt
    Dec 14, 2013 at 5:09
  • 2
    @BenVoigt: It is a pointer to an array object, so 5.7p4 doesn't apply. Although, I would tend to think this is a defect. I think 5.7p4 should read "..., a pointer that isn't a pointer to an element of an array..." instead of "..., a pointer to a nonarray object..." Dec 14, 2013 at 5:13
  • Yes, clearly the intent is the behavior I gave in my comment when paraphrasing. Or perhaps a pointer to an array object is considered also a pointer to its first element, which makes the pointer arithmetic valid.
    – Ben Voigt
    Dec 14, 2013 at 5:18

It is undefined behavior in C, dereferencing a pointer that points beyond an existing object always is unless it is itself part of a bigger object that contains more elements.

But the basic idea of using &array + 1 is correct, whenever array is an lvalue. (There are cases where arrays aren't lvalues.) In that case that is a valid pointer operation. Now to obtain a pointer to the first element you just have to cast that back to the base type. In your case that would be

(int*)(&array + 1)

The value of a pointer to array is guaranteed to be the same value as a pointer to its first element, only the types differ.

Unfortunately I don't see a way to make such an expression type agnostic such that you could put this in a generic macro, unless you cast to void*. (With the gcc typeof extension you could do, e.g) So you'd better stick to the portable (array)+ARRAYLEN(array), that one should work in all cases.

In a weird corner case an array that is part of a struct and is returned as rvalue from a function is not an lvalue. I think that the standard allows pointer arithmetic here, too, bu t I never understood that construction completely, so I am not sure that it will work in that case.

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