Is it undefined behaviour to use pointer after allocated memory?

Question

I have the following code:

uint8_t buffer[16];
uint8_t data[16];
uint8_t buffer_length = 16;
uint8_t data_length = 0;

memcpy(buffer + buffer_length, data, data_length);

memcpy should be a no-op, because data_length is zero. However buffer + buffer_length points just outside of the allocated memory. I wonder if it could trigger some kind of undefined behaviour? Should I wrap this memcpy with an additional if?

I understand that any reasonable implementation of memcpy would work fine, however this question is more from the code correctness perspective and avoiding undefined behaviours.

Answer 1

As the answer of Stephen C points out, the C17 specification is a bit vague about whether or not this is well-defined.

However, the C23 specification clarifies this in a footnote to the part of 7.1.4 stating

If a function argument is described as being an array, the pointer passed to the function shall have a value such that all address computations and accesses to objects (that would be valid if the pointer did point to the first element of such an array) are valid.

The footnote (235) reads:

This includes, for example, passing a valid pointer that points one-past-the-end of an array along with a size of 0, or using any valid pointer with a size of 0.

The first part of the sentence explicitly defines the OP case as well-defined.

Adding this statement can be seen as admitting that the C17 specification is not sufficiently clear on this point and thus, it cannot be ruled out that an implementer of a C17 compiler may in good faith interpret the standard such that this case is not defined behavior.

However, C23 should remove that uncertainty.

Answer 2

The code has well-defined behavior.

The "string handling functions" that the memcpy function sorts under states (C17 7.24.1):

Where an argument declared as size_t n specifies the length of the array for a function, n can have the value zero on a call to that function. Unless explicitly stated otherwise in the description of a particular function in this subclause, pointer arguments on such a call shall still have valid values, as described in 7.1.4.

The part in C17 7.1.4 regarding array parameters passed to standard library functions is somewhat relevant:

If a function argument is described as being an array, the pointer actually passed to the function shall have a value such that all address computations and accesses to objects (that would be valid if the pointer did point to the first element of such an array) are in fact valid.

(The arguments to memcpy need not necessarily be an array/arrays however. But in this case they both are.)

Address computations and the following access to an item of the array are defined by the rules for pointer arithmetic, specifically C17 6.5.6 §8 about the additive operators, the relevant part being this one:

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. 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.

Therefore buffer + buffer_length is explicitly allowed by this "point one item past the end of an array" special rule, as long as we don't de-reference that location. Which will not happen in this case. Had we written buffer + buffer_length + 1 then it would be an invalid address computation and undefined behavior.

Answer 3

If the question is whether an conforming implementation could process such pointer constructs in gratuitously wacky fashion, the answer is almost certainly yes. If the question is whether programmers should be expected to jump through hoops to allow for such possibility, the answer is no. The Standard treats many such judgments as quality of implementation issues outside its jurisdiction.

In both clang and gcc, an equality comparison between a pointer to the start of an object, and a a legitimately formed "one past" pointer for the object that happens to immediately precede it in memory, may have side effects which are consistent neither with the comparison yielding 0, nor with it yielding 1. It would not, however, would probably not render such compilers non-conforming, because there would almost certainly exist some possible program which nominally exercises the translation limits in N1570 5.2.4.1, which clang and gcc would process correctly.

If there were an implementation that were incapable of correctly processing any program that exercises the translation limits in N5.2.4.1, other than one which passes a just-past pointer to memcpy with a size argument of zero, then one could argue that failure to treat that operation as a no-op might render the implementation non-conforming, or one could argue that because the Standard fails to unambiguously make clear that such behavior is required, the Standard would impose no requirements on a program that performs such an operation, but neither of those arguments would detract from the fact that quality implementations should be expected to treat the operation as a no-op, but the Standard would allow poor quality implementations to process such constructs in nonsensical fashion. Since the Standard deliberately waives jurisdiction over such quality-of-implementation issues, it should not be used as a source of guidance on such matters.