When working with arrays, standard algorithms (in both C and C++) often return pointers to elements. It is sometimes convenient to have the index of the element, perhaps to index into another array, and I normally get that by subtracting the beginning of the array from the pointer:

int arr[100];
int *addressICareAbout = f(arr, 100);
size_t index = addressICareAbout - arr;

This always seemed simple and effective enough. However, it was recently pointed out to me that pointer subtraction actually returns a ptrdiff_t and that, in principle, there could be problems if the "index" doesn't fit in a ptrdiff_t. I didn't really believe that any implementation would be perverse enough to allow one to create such a large arr (and thereby cause such issues), but the accepted answer here admits that that's possible and I've found no evidence to suggest otherwise. I've therefore resigned myself to this being the case (unless someone can convince me otherwise) and will be careful going forward. That answer proposes a fairly convoluted method of "safely" getting the index; is there really nothing better?

That said, I'm confused about a possible workaround in C++. There we have std::distance, but is std::distance(arr, addressICareAbout) guaranteed to be well-defined? On the one hand, (the pointer to the first element of) arr can be incremented to reach addressICareAbout (right?), but on the other hand std::distance should return a ptrdiff_t. The iterators for the standard containers can (presumably) have the same issues.

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    Yes std::distance does exactly what you are describing. For example your pointer arithmetic trick only works with contiguous containers, it would fail for std::list. On the other hand std::distance handles both contiguous and non-contiguous containers, as long as they are ordered. – CoryKramer May 8 '15 at 12:03
  • Your post is interesting but I can't see a question. Are you asking, "what type should I use to store pointer offsets?". If so, the answer is a ptrdiff_t. – Richard Hodges May 8 '15 at 12:16
  • I have 1.5 questions: 1.0) In C++, can std::distance be used "safely" for containers or do I have to worry that the distance might overflow difference_type? 0.5) Is the situation in C (working with pointers) really as bad as it seems? – Joshua Green May 8 '15 at 12:25
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    from en.cppreference.com/w/cpp/types/ptrdiff_t If an array is so large (greater than PTRDIFF_MAX elements, but less than SIZE_MAX bytes), that the difference between two pointers may not be representable as std::ptrdiff_t, the result of subtracting two such pointers is undefined. Hence, great question. – franji1 May 8 '15 at 12:35
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    Doesn't the linked question itself provide the workaround? Insert PTRDIFF_MAX somewhere into your allocation system to prevent overflow being an option. Yes the standard doesn't make the ruling about PTRDIFF_MAX being helpful for this, but the implementation would be effectively broken if you couldn't rely on it to give a useful value here. – Leushenko May 8 '15 at 12:48

It is extremely unlikely that you will ever have two pointers to the same array where the difference doesn't fit into ptrdiff_t.

On 64 bit implementations, ptrdiff_t is signed 64 bit, so you'd need an array of 8 billion gigabytes. On 32 bit implementations, usually your total address space is limited to 3 GB, 3 1/4 GB if you are lucky (it's address space, not RAM, that counts), so you'd need an array of more than 2 GB which doesn't leave much for anything else. And it is quite possible that malloc will refuse to allocate an array of that size in the first place. Your judgement of course.

While std::distance has advantages, I suspect it has the same theoretical problem as ptrdiff_t, since distances can be positive and negative, and it's probably not a 64 bit type on a 32 bit implementation.

Note that if you can allocate a 3 GB array on a 32 bit implementation, and you have two int* to the first and the last element of that array, I wouldn't be surprised if the pointer difference is calculated incorrectly even though the result fits into ptrdiff_t.

  • The difference would be -1gigabyte, which if added to the first address would yield the second (due to arithmetic overflow). – Richard Hodges May 8 '15 at 12:38
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    @RichardHodges: Signed overflow has no guarantees in C++. Prior conversion to unsigned could get you there if you're careful. – Lightness Races with Monica May 8 '15 at 12:40
  • I know that 32 bit compilers can support 64 bit integers (as long long int), so in those implementations, ptrdiff_t COULD be defined as long long int, and it would "just work" (but you have to make sure you use ptrdiff_t and NOT just int. – franji1 May 8 '15 at 12:51
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    "you'd need an array of more than 2 GB".... No, you'd need an array with more than 2 billion elements. For an array of int on a 32-bit system, that means 8 GB, which can't possibly fit in the address space. The issue can only potentially occur for sizeof (T) == 1. – Ben Voigt May 8 '15 at 15:15
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    GCC (and possibly others) will assume that objects occupy no more than half the address space anyway: gcc.gnu.org/ml/gcc/2011-08/msg00221.html – Tavian Barnes May 8 '15 at 15:28

Possible workaround:

Cast both pointers to uintptr_t, subtract, and divide by sizeof (T) yourself. This is not precisely portable, but it's guaranteed never to be undefined behavior, and most systems specify integer<->pointer conversion in a way that makes this work.

Really portable (but less efficient) workaround:

Use an alternative base pointer. If the array is more than 2<<30 elements, then you can legally compute step = p1 + (2<<30), use relational operators to see whether p2 > step, and if so, calculate the offset as (2u << 30) + uintptr_t(distance(step, p2)) Note that the recursive call may require taking another step.

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    Converting to uintprt_t is not portable. I've worked on systems (Cray vector systems) where this would not work. On those systems, byte pointers are implemented as 64-bit word pointers with a 3-bit offset stored in the high-order 3 bits; pointer-to-integer conversion just copies the bits. I suspect you're more likely to encounter a system where converting to uintptr_t will fail than one where straightforward pointer subtraction will overflow. And I don't know what you mean by "guaranteed never to be implementation-defined behavior". – Keith Thompson May 8 '15 at 15:24
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    The standard guarantees that you can convert a void* to uintptr_t (which might not even exist) and back to void*, and the result will compare equal to the original pointer. If you perform arithmetic on the uintptr_t value, the standard guarantees nothing. The resulting pointer is implementation-defined and may be a trap representation, so just evaluating the pointer has undefined behavior. – Keith Thompson May 8 '15 at 15:27
  • @KeithThompson: But I'm not casting back to a pointer, let alone dereferencing one, there is no undefined behavior. – Ben Voigt May 8 '15 at 15:28
  • Ah, you're right, the idea is to compute an integer index. But the index might be meaningless, and using it to index into the array could have undefined behavior. – Keith Thompson May 8 '15 at 15:30
  • @KeithThompson: Yes, but you can portably check whether it worked. if (index < element_count && p2 == p1 + index) – Ben Voigt May 8 '15 at 15:31

I've found no evidence to suggest otherwise.

Fortunately there is evidence here: http://en.cppreference.com/w/cpp/types/size_t

std::size_t can store the maximum size of a theoretically possible object of any type (including array). A type whose size cannot be represented by std::size_t is ill-formed (since C++14)

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    True, size_t must be large enough to store the size of arr. But must ptrdiff_t be large enough to store any index? – Joshua Green May 8 '15 at 12:29
  • To clarify, it seems that the subtraction is already undefined if the difference overflows a ptrdiff_t, regardless of what type of variable I'd like to assign the result to. – Joshua Green May 8 '15 at 12:32
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    The problem isn't "larger than the maximum size of an array". The problem is that ptrdiff_t must handle positive and negative numbers, and you might have an array with a size larger than the largest possible ptrdiff_t (not larger than the largest possible size_t). – gnasher729 May 8 '15 at 12:38
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    How does this answer the question? (Hint: it doesn't) – Lightness Races with Monica May 8 '15 at 12:41
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    Overflowing signed types is undefined while casting an unsigned type to a signed type that can't hold the value is implementation defined. I'd hate to rely on either of these. – Joshua Green May 8 '15 at 12:42

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