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The following example is from Wikipedia.

int arr[4] = {0, 1, 2, 3};
int* p = arr + 5;  // undefined behavior

If I never dereference p, then why is arr + 5 alone undefined behaviour? I expect pointers to behave as integers - with the exception that when dereferenced the value of a pointer is considered as a memory address.

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I am fairly sure the "undefined" part is just the standard saying that it cannot tell you where that pointer is pointing now. Like most pointer "undefined" things, I am sure it is fine to make it, but illegal to deference it. –  Lalaland May 6 '12 at 19:35
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@EthanSteinberg: That'd only be true if they said the resulting value was undefined. If the behavior is undefined, it's not safe to execute it, even if you never dereference it. –  Mehrdad May 6 '12 at 19:36
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Pointers are not intergers. Under the hood, the representation may coincidence, but as far as the "C++ abstract machine" is concerned, those are entirely different things that happen to share some syntax, like struct { int a; int x; } and struct { char x; }. –  delnan May 6 '12 at 19:37
    
possible duplicate of C++ Accesses an Array out of bounds gives no error, why? Not for the question as much as the top answer to this question. –  Tony May 6 '12 at 19:40
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Because not all machines behave the same way as you PC. You are expecting a certain behavior based on how it works on your machine. The standards committee has more experience and understands that other architectures implements pointers differently thus can not guarantee the above behavior over all platforms (thus it is undefined). –  Loki Astari May 6 '12 at 19:48

5 Answers 5

up vote 10 down vote accepted

That's because pointers don't behave like integers. It's undefined behavior because the standard says so.

On most platforms however (if not all), you won't get a crash or run into dubious behavior if you don't dereference the array. But then, if you don't dereference it, what's the point of doing the addition?

That said, note that an expression going one over the end of an array is technically 100% "correct" and guaranteed not to crash per §5.7 ¶5 of the C++11 spec. However, the result of that expression is unspecified (just guaranteed not to be an overflow); while any other expression going more than one past the array bounds is explicitly undefined behavior.

Note: That does not mean it is safe to read and write from an over-by-one offset. You likely will be editing data that does not belong to that array, and will cause state/memory corruption. You just won't cause an overflow exception.

My guess is that it's like that because it's not only dereferencing that's wrong. Also pointer arithmetics, comparing pointers, etc. So it's just easier to say don't do this instead of enumerating the situations where it can be dangerous.

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How is going one over the bounds fine? –  Mahmoud Al-Qudsi May 6 '12 at 19:39
    
@MahmoudAl-Qudsi The standard says it's fine, that's how. –  delnan May 6 '12 at 19:40
    
@MahmoudAl-Qudsi it just is :) There's a lot of stuff that depends on it. Like std iterators. –  Luchian Grigore May 6 '12 at 19:40
    
Can you clarify your post? Per §5.7 ¶5 of the C++11 spec, it's only the expression that is valid (i.e. guaranteed not to overflow/no exceptions), but not the result. I know you didn't say the result was defined, but it could easily be misconstrued as such. "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." –  Mahmoud Al-Qudsi May 6 '12 at 19:49
    
@MahmoudAl-Qudsi I thought that's what I said... –  Luchian Grigore May 6 '12 at 19:55

"Undefined behavior" doesn't mean it has to crash on that line of code, but it does mean that you can't make any guaranteed about the result. For example:

int arr[4] = {0, 1, 2, 3};
int* p = arr + 5; // I guess this is allowed to crash, but that would be a rather 
                  // unusual implementation choice on most machines.

*p; //may cause a crash, or it may read data out of some other data structure
assert(arr < p); // this statement may not be true
                 // (arr may be so close to the end of the address space that 
                 //  adding 5 overflowed the address space and wrapped around)
assert(p - arr == 5); //this statement may not be true
                      //the compiler may have assigned p some other value

I'm sure there are many other examples you can throw in here.

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arr+5 is not one-past-the-end it's two-past-the-end, therefore it's UB according to §5.7 ¶5 and it could crash on a machine that has trap representations for pointers. –  Jonathan Wakely May 6 '12 at 20:01
    
That was in reply to a comment which has been deleted, please ignore the "not one-past-the-end" part. The rest still applies, it could crash, but I agree that would be unusual. –  Jonathan Wakely May 6 '12 at 20:07

The original x86 can have issues with such statements. On 16 bits code, pointers are 16+16 bits. If you add an offset to the lower 16 bits, you might need to deal with overflow and change the upper 16 bits. That was a slow operation and best avoided.

On those systems, array_base+offset was guaranteed not to overflow, if offset was in range (<=array size). But array+5 would overflow if array contained only 3 elements.

The consequence of that overflow is that you got a pointer which doesn't point behind the array, but before. And that might not even be RAM, but memory-mapped hardware. The C++ standard doesn't try to limit what happens if you construct pointers to random hardware components, i.e. it's Undefined Behavior on real systems.

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If arr happens to be right at the end of the machine's memory space then arr+5 might be outside that memory space, so the pointer type might not be able to represent the value i.e. it might overflow, and overflow is undefined.

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Some systems, very rare systems and I can't name one, will cause traps when you increment past boundaries like that. Further, it allows an implementation that provides boundary protection to exist...again though I can't think of one.

Essentially, you shouldn't be doing it and therefor there's no reason to specify what happens when you do. Specifying what happens puts unwarranted burden on the implementation provider.

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Systems that can do that are actually quite common, with Intel x86 (and compatibles) as a prime example. It's not usually used that way, but the x86's segment-based memory protection works as described -- it can throw an exception for even attempting to form an invalid address. Most typical OSes, however, set up all segments with a base of 0 and a limit of 4Gig, making all possible offsets valid. For what it's worth, this capability was actually used in OS/2 1.x. –  Jerry Coffin May 6 '12 at 23:07
    
@JerryCoffin: I wish Intel had used 32-bit segment registers on the 80386, with the upper portion selecting a segment descriptor and the lower portion acting as a scaled multiplier whose behavior would be controlled by that segment descriptor. Such an architecture would have made it possible to use 32-bit object references without a four gigabyte addressing limit (the number of distinct objects would be limited to well under four billion, but their total size could be much greater). –  supercat Jul 9 '14 at 17:47

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