74

Suppose you have an array:

int array[SIZE];

or

int *array = new(int[SIZE]);

Does C or C++ guarantee that array < array + SIZE, and if so where?

I understand that regardless of the language spec, many operating systems guarantee this property by reserving the top of the virtual address space for the kernel. My question is whether this is also guaranteed by the language, rather than just by the vast majority of implementations.

As an example, suppose an OS kernel lives in low memory and sometimes gives the highest page of virtual memory out to user processes in response to mmap requests for anonymous memory. If malloc or ::operator new[] directly calls mmap for the allocation of a huge array, and the end of the array abuts the top of the virtual address space such that array + SIZE wraps around to zero, does this amount to a non-compliant implementation of the language?

Clarification

Note that the question is not asking about array+(SIZE-1), which is the address of the last element of the array. That one is guaranteed to be greater than array. The question is about a pointer one past the end of an array, or also p+1 when p is a pointer to a non-array object (which the section of the standard pointed to by the selected answer makes clear is treated the same way).

Stackoverflow has asked me to clarify why this question is not the same as this one. The other question asks how to implement total ordering of pointers. That other question essentially boils down to how could a library implement std::less such that it works even for pointers to differently allocated objects, which the standard says can only be compared for equality, not greater and less than.

In contrast, my question was about whether one past the end of an array is always guaranteed to be greater than the array. Whether the answer to my question is yes or no doesn't actually change how you would implement std::less, so the other question doesn't seem relevant. If it's illegal to compare to one past the end of an array, then std::less could simply exhibit undefined behavior in this case. (Also, typically the standard library is implemented by the same people as the compiler, and so is free to take advantage of properties of the particular compiler.)

17
  • 15
    Who said that a pointer has to be an actual memory address? Mar 2, 2021 at 6:29
  • 4
    @S.M. That's about ordering pointers to different objects. This question is just about pointers within the same array.
    – Barmar
    Mar 2, 2021 at 6:40
  • 10
    @user3188445 From the non-authoritative but generally reliable cppreference, in C++ "If one pointer points to an element of an array, or to a subobject of the element of the array, and another pointer points one past the last element of the array, the latter pointer compares greater".
    – dxiv
    Mar 2, 2021 at 6:41
  • 20
    Luckily it is guaranteed, because otherwise an awful lot of code out there would be broken. It's very common to see for (int *p = array; p < array + SIZE; p++) do_stuff(*p); Mar 2, 2021 at 6:44
  • 7
    @АлексейНеудачин The standard doesn't mention virtual addresses, or pages, or descriptor tables. If it says that &obj < &obj + 1 must be true, then any compiler that doesn't do that (for any reason) is bugged. And, in practice, < comparison shouldn't read from the addresses being compared, so the pointer being invalid doesn't matter. Mar 2, 2021 at 17:55

6 Answers 6

80
+50

Yes. From section 6.5.8 para 5.

If the expression P points to an element of an array object and the expression Q points to the last element of the same array object, the pointer expression Q+1 compares greater than P.

Expression array is P. The expression array + SIZE - 1 points to the last element of array, which is Q. Thus:

array + SIZE = array + SIZE - 1 + 1 = Q + 1 > P = array

19
  • 4
    Does this imply that you cannot create an implementation that puts an array at the top of the address space? Because (array= ((int*)0xFFFFFFFC))+ 1 might be 0x00000000? (32-bit address space, 4-byte int example)
    – Wyck
    Mar 2, 2021 at 15:32
  • 7
    @Wyck, you might not be able to put anything at the top position of the address space, if I'm reading cppreference.com correctly: "a pointer to an object that is not an element of an array is treated as if it were pointing to an element of an array with one element"
    – ilkkachu
    Mar 2, 2021 at 16:06
  • 7
    @ilkkachu: Objects whose address is not taken could be placed at the top of address space or at whatever physical address would match a null pointer's representation. Since most non-trivial programs will have at least two objects whose address is not taken, a requirement that any objects whose address is taken have to go elsewhere doesn't reduce the amount of practically useful storage.
    – supercat
    Mar 2, 2021 at 16:12
  • 11
    @Wyck - it doesn't prohibit such an implementation, as long as it ensures that < is consistent with it. Mar 2, 2021 at 20:15
  • 4
    @Wyck : You seem to be conflating the runtime values of the variables array, SIZE, P, and Q with actual virtual memory addresses. Sure, having pointers contain bit patterns identical to virtual memory addresses is an easy implementation, but it is not mandatory. As a concrete example, a pointer to a (16-bit) word at an odd address on an MC68000 cannot be directly dereferenced since non-byte dereferencing an odd address on that architecture throws exceptions. Mar 2, 2021 at 22:54
22

C requires this. Section 6.5.8 para 5 says:

pointers to array elements with larger subscript values compare greater than pointers to elements of the same array with lower subscript values

I'm sure there's something analogous in the C++ specification.

This requirement effectively prevents allocating objects that wrap around the address space on common hardware, because it would be impractical to implement all the bookkeeping necessary to implement the relational operator efficiently.

12
  • 5
    Note, that array + SIZE does not point to any element of array. It points to element just after the last one.
    – tstanisl
    Mar 2, 2021 at 6:41
  • I think arrays are defined to their size + 1, but I'm not sure how to look that up.
    – Neil
    Mar 2, 2021 at 6:43
  • 19
    @Neil You're allowed to form a pointer just past the end, but not allowed to dereference it.
    – Barmar
    Mar 2, 2021 at 6:45
  • 4
    The “bookkeeping necessary to implement the relational operator efficiently” is trivial: p < q, p = q, and p > q are equivalent to p−q < 0, p−q = 0, and p−q > 0, where p−q is computed in the width of the address space bits. As long as every supported object is less than half the size of the address space, p−q must fall in the right region. Mar 2, 2021 at 11:58
  • 1
    @jwdonahue I'm well familiar with non-traditional implementations, I used C on Lisp Machines.
    – Barmar
    Mar 3, 2021 at 19:16
13

The guarantee does not hold for the case int *array = new(int[SIZE]); when SIZE is zero .

The result of new int[0] is required to be a valid pointer that can have 0 added to it , but array == array + SIZE in this case, and a strictly less-than test will yield false.

2
  • 10
    You got me, I should have specified I was assuming SIZE > 0... Mar 3, 2021 at 2:51
  • @user3188445 @M.M - Really, the upshot here is that the question should be whether or not it's guaranteed that array <= array + SIZE.
    – Aiken Drum
    Mar 9, 2021 at 3:11
8

This is defined in C++, from 7.6.6.4 (p139 of current C++23 draft):

When an expression J that has integral type is added to or subtracted from an expression P of pointer type, the result has the type of P.

(4.1) — If P evaluates to a null pointer value and J evaluates to 0, the result is a null pointer value.

(4.2) — Otherwise, if P points to an array element i of an array object x with n elements (9.3.4.5) the expressions P + J and J + P (where J has the value j) point to the (possibly-hypothetical) array element i + j of x if 0 <= i + j <= n and the expression P - J points to the (possibly-hypothetical) array element i − j of x if 0 <= i − j <= n.

(4.3) — Otherwise, the behavior is undefined.

Note that 4.2 explicitly has "<= n", not "< n". It's undefined for any value larger than size(), but is defined for size().

The ordering of array elements is defined in 7.6.9 (p141):

(4.1) If two pointers point to different elements of the same array, or to subobjects thereof, the pointer to the element with the higher subscript is required to compare greater.

Which means the hypothetical element n will compare greater than the array itself (element 0) for all well defined cases of n > 0.

4
  • 1
    That says you can create such a pointer, it doesn't say how comparison behaves with it.
    – user9876
    Mar 3, 2021 at 16:03
  • You're right. I assumed the OP was satisfied that array members were strongly ordered. Updated answer to cover this.
    – throx
    Mar 3, 2021 at 22:05
  • Your addition still doesn't cover this. P+n points to a "hypothetical array element". Hypothetical meaning (in this case) "does not exist". P+n does NOT really point to an array element. So 4.1 cannot apply, since P+n does not point to an "element of the ... array".
    – user9876
    May 5, 2021 at 0:20
  • As noted in Richard Smith's answer below, this is covered in [basic.compound] as valid, and 4.1 explicitly does apply.
    – throx
    May 6, 2021 at 1:25
5

The relevant rule in C++ is [expr.rel]/4.1:

If two pointers point to different elements of the same array, or to subobjects thereof, the pointer to the element with the higher subscript is required to compare greater.

The above rule appears to only cover pointers to array elements, and array + SIZE doesn't point to an array element. However, as mentioned in the footnote, a one-past-the-end pointer is treated as if it were an array element here. The relevant language rule is in [basic.compound]/3:

For purposes of pointer arithmetic ([expr.add]) and comparison ([expr.rel], [expr.eq]), a pointer past the end of the last element of an array x of n elements is considered to be equivalent to a pointer to a hypothetical array element n of x and an object of type T that is not an array element is considered to belong to an array with one element of type T.

So C++ guarantees that array + SIZE > array (at least when SIZE > 0), and that &x + 1 > &x for any object x.

-8

array is guaranteed to have consecutive memory space inside. after c++03 or so vectors is guaranteed to have one too for its &vec[0] ... &vec[vec.size() - 1]. This automatically means that that what you're asking about is true
it's called contiguous storage . can be found here for vectors
http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2018/p0944r0.html

The elements of a vector are stored contiguously, meaning that if v is a vector<T, Allocator> where T is some type other than bool, then it obeys the identity &v[n] == &v[0] + n for all 0 <= n < v.size(). Presumably five more years of studying the interactions of contiguity with caching made it clear to WG21 that contiguity needed to be mandated and non-contiguous vector implementation should be clearly banned.

latter is from standard docs. C++03 I've guessed right.

11
  • I think you confused * and &.
    – MSalters
    Mar 2, 2021 at 8:11
  • 2
    Where does the spec make this guarantee about arrays? What does "consecutive memory space" mean, exactly? (This seems hard to define, given that the spec doesn't even say that pointers are "numbers" in any meaningful sense.) Why does "consecutive memory space" imply "pointer does not overflow"? Mar 2, 2021 at 15:55
  • 4
    My question was about vec[size()] not vec[size()-1]. Mar 2, 2021 at 17:45
  • 1
    If you're looking for proof that arrays are contiguous, it's in [dcl.array]/6. But as noted by Daniel Wagner, this alone doesn't strictly prove that array < array + SIZE == true. Mar 2, 2021 at 17:57
  • 1
    No, it is guaranteed. See Section 6.5.8 para 5 of the C lsnguage spec, as linked in the selected answer. Mar 2, 2021 at 18:01

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.