C++ standard (and C for that matter) allows to create (not dereference though) a pointer to one element past the end of the array. Does this mean that an array will never be allocated at such a location that its last element ends at the memory boundary? I understand that in practice some/all implementation might follow this convention, but which one the following is true:

  1. It's actually false, and an array might end at memory boundary, OR
  2. It is mandated by C++ standard to end at least one element's worth of memory before the boundary, OR
  3. Neither 1, nor 2, but it is still like that in actual compilers because it makes implementation easier.

Is anything different for the case of C?

Update: It seems like 1 is the correct answer. See answer from James Kanze below, and also see efence (http://linux.die.net/man/3/efence - thanks to Michael Chastain for the pointer to it)

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    I don't think the standard, certainly for C++ mandates anything about memory allocation wrt to this so 1 and 2 would not be true and probably 3 is more likely an implementation detail – EdChum Oct 17 '14 at 7:53
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    I should clarify my first comment, for 1 it might end at a memory boundary but this is not something that is specified in the standard and would be up to the implementor – EdChum Oct 17 '14 at 8:03
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    @JamesKanze : my point was that 0x40000000 can be stored into a 32-bit pointer variable, whereas 0x100000000 couldn't. So, having a pointer one past the end of the array can be trivially made to work, except if that pointer would overflow the pointer type. And that could only happen if the addressable range meets or exceeds the range of the pointer type. I can't think of a platform where that's true. Obviously, trap conditions can exist (like you point out in your answer), but those can be worked around. – Sander De Dycker Oct 17 '14 at 8:43
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    @SanderDeDycker It can always be made to work; just don't use the last byte/word of the allocated block. As for machines where the addressable range exceeds the range of the pointer type: there's Intel, if your pointers don't include the segment register. – James Kanze Oct 17 '14 at 8:52
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    @abi: I prefer to think of pointers as pointing to spaces "between" memory locations, and saying that "*foo" means "the thing immediately following the place foo points". A 12" ruler has thirteen markings at 0", 1", 2", up to 12", and has 12 spaces between markings; each of the twelve inches has a mark at the beginning and a mark at the end. Under such a viewpoint, the 12" mark is simply a mark like any other, even though nothing follows it. – supercat Oct 17 '14 at 22:13

An implementation must allow a pointer to one past the end to exist. How it does this is its business. On many machines, you can safely put any value into a pointer, without risk (unless you dereference it); on such systems, the one past the end pointer may point to unmapped memory—I've actually encountered a case under Windows where it did.

On other machines, just loading a pointer to unmapped memory into a register will trap, causing the program to crash. On such machines, the implementation must ensure that this doesn't happen, either by refusing to use the last byte or word of allocated memory, or by ensuring that all use of the pointer other than dereferencing it avoids any instructions which might cause the hardware to treat it as an invalid pointer. (Most such systems have separate address and data registers, and will only trap if the pointer is loaded into an address register. If the data registers are large enough, the compiler can safely load the pointer into a data register for e.g. comparison. This is often necessary anyway, as the address registers don't always support comparison.)

Re your last question: C and C++ are exactly identical in this respect; C++ simply took over the rules from C.

  • This is very informative. And quite crazy/scary. I never would reasonably excpect that I am not allowed to manipulate pointers to wherever the f** I please. This actually kindof invalidates things I have implemented in the past (end iterator pointing to unmapped memory). Are such systems usually paged (therefore reducing the chance of trapping due to large chunks of memory getting mapped) ? – v.oddou Oct 17 '14 at 8:50
  • @v.oddou There are a lot of machines where this is the case. Starting with Intel architecture, if you use the segment registers. (Loading an invalid segment into a segment register will trap. Most compilers today don't support it, but I've worked on Intel with 48 bit pointers, and just reading a random pointer value could trap.) – James Kanze Oct 17 '14 at 8:55
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    @v.oddou Or as I once saw written in the early days of C: "Ah, for the good old days, when men were men, women were women, and pointers were ints." It seems like we've come the full circle, and that once again, most people today think that pointers must map to some integral type. (Back in the days when I was learning C, the machines I worked on were mostly 16 bit, but we had far more than 64K memory. And all sorts of "structured" pointers to address it. And then, there were the 36 bit word addressed machine, in which the byte address and size of a char* were in the high order bits.) – James Kanze Oct 17 '14 at 9:00
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    @psyill Then this quote covers it. It's a pretty standard idiom: in modern C++ for ( p = std::begin(a); p != std::end(a); ++ p ) will leave p pointing to one past the end. – James Kanze Oct 17 '14 at 16:48
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    @James Kanze Disagree about " Today, when 32 bit systems are more or less a minimum". With embedded processors, at least 100s of million per year in 2014 use 16-bit int and C is very popular there. Do not have numbers about all processors made in 2013, but I would not be surprised if most processors today are sub 32-bit. – chux Oct 17 '14 at 18:52

There's an interesting passage at §3.9.2/3 [Compound types]:

The type of a pointer to void or a pointer to an object type is called an object pointer type. [...] A valid value of an object pointer type represents either the address of a byte in memory (1.7) or a null pointer (4.10).

Together with the text at §5.7/5 [Additive operators]:

[...] Moreover, if the expression P points to the last element of an array object, the expression (P)+1 points one past the last element of the array object, and if the expression Q points one past the last element of an array object, the expression (Q)-1 points to the last element of the array object.

it seems that an array ending at the last byte in memory can not be allocated, if there is a requirement that the one-past-the-end pointer must be valid. If the one-past-the-end pointer is allowed to be invalid, I don't know the answer.

The section § [Deallocation functions] states that:

The effect of using an invalid pointer value (including passing it to a deallocation function) is undefined.

Thus if comparing a one-past-the-end pointer for an allocated array must be supported, the one-past-the-end pointer must be valid.

Based on the comments I got, I assume that an implementation can allocate an array without having to care about if the array's one-past-the-end pointer is usable or not. However I would like to find out the relevant passages in the standard for this.

  • Your quote of 5.7/5 does not say that the one-past-the-end pointer needs to be valid. – rubenvb Oct 17 '14 at 8:50
  • No, it does not do so explicitly. I'm trying to figure out if there is some other part of the standard which put a requirement on the ability to use a one-past-the-end pointer. – psyill Oct 17 '14 at 8:55
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    Your conclusion is wrong (and I've actually seen a case once where the end of the array was at the absolute end of the allocated block). All that is required is that the operations (other than dereferencing) on such a pointer work. Which they will in most current environments. – James Kanze Oct 17 '14 at 9:02
  • That means that there's nothing in the standard requiring the ability of using each possible one-past-the-end pointer then? – psyill Oct 17 '14 at 9:09
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    The snippet foo* end = myarray+ arraylen; for (foo* p = myarray; p != end; p++) works even if myarray+arraylen evaluates to NULL (or (foo*)0). You just shouldn't use p<end instead. – Hagen von Eitzen Oct 17 '14 at 15:00

You're half right. Suppose a hypothetical implementation uses linearly addressed memory and pointers that are represented as 16-bit unsigned integers. Suppose also that the null pointer is represented as zero. And finally, suppose you ask to for 16 bytes of memory, with char *p = malloc(16);. Then it's guaranteed that you will get a pointer of which the numeric value is less than 65520. The value 65520 itself wouldn't be valid, because as you rightly point out, assuming the allocation succeeded, p + 16 is a valid pointer that must not be a null pointer.

However, suppose now that a hypothetical implementation uses linearly addressed memory and pointers that are represented as 32-bit unsigned integers, but only has an address space of 16 bits. Suppose also again that the null pointer is represented as zero. And finally, suppose again that you ask for 16 bytes of memory, with char *p = malloc(16);. Then it's only guaranteed that you will get a pointer of which the numeric value is less than or equal to 65520. The value 65520 itself would be valid, so long as the implementation makes sure that adding 16 to that gives you the value 65536, and that subtracting 16 gets you back to 65520. This is valid even if no memory (physical or virtual) exists at all at address 65536.

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    I like the hypotethical consideration that a block of memory could be returned so high that the end pointer would overflow and wrap. – v.oddou Oct 17 '14 at 8:58

The standard states explicitly what happens when you increment the pointer to the last element. It gives you a value that can only be used as comparison to check if you're at or before the end of the array or not. The pointer may well point to validly allocated memory for some other object, but that is complete undefined (implementation defined?) behaviour and using that pointer as such is definitely undefined behaviour.

What I'm getting at is that the one-past-the-end pointer is just that: it is the pointer you get when you increment the pointer to the last element, to mark the end of the array in a very cheap way. But do note that comparing pointers of unrelated objects is completely nonsensical (and even undefined behaviour if I'm not mistaken). So the fact that there might be overlap in pointer "values" across different objects is a non-issue, as in exploiting this you enter the Land of Undefined Behaviour..

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    The first paragraph is completely false. If you increment a null pointer, you have undefined behavior. Some implementations allow just about anything in a pointer, others don't. – James Kanze Oct 17 '14 at 8:20
  • @rubenvb: I think you missed the fact that there is the notion of a "safely-derived" pointer. – Mehrdad Oct 17 '14 at 8:24
  • @James Is this explanation better? – rubenvb Oct 17 '14 at 8:38
  • It's slightly misleading. "compare if you're at the end or not" suggests it only allows operator==, but operator< is also OK. you can check if a pointer is before the end. A compiler is allowed to optimize operatoar< to operator != in this case! – MSalters Oct 17 '14 at 9:13

This depends on implementation. At least in visual C++ without using any from of array bound checking, you could create a pointer any number of elements past the end of the array. If you dereference it it will still work as long as the memory address that you are accessing is within the allocated heap/stack of your program. You will read/modify whatever the value in that memory location. If the address is outside the allocated memory space it will give an error.

Debuggers has checks to detect these, as this kind of coding create bugs very difficult to track.

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    The question is not about VC++, but about what the standard mandates. – Matteo Italia Oct 17 '14 at 8:10
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    you could create a pointer any number of elements past the end of the array VC++ may allow UBs (and "work") but that doesn't answer the question. – P.P. Oct 17 '14 at 8:10

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