As verbose said, this yields undefined behavior. A bit more precision follows.

5.2.1/1 says

[...] The expression E1[E2] is identical (by definition) to *((E1)+(E2))

Hence, `val[i]`

is equivalent to `*((val)+i))`

. Since `val`

is an array, the array-to-pointer conversion (4.2/1) occurs before the addition is performed. Therefore, `val[i]`

is equivalent to `*(ptr + i)`

where `ptr`

is an `int*`

set to `&val[0]`

.

Then, 5.7/2 explains what `ptr + i`

points to. It also says (emphasis are mine):

[...] 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**.

In the case of `ptr + i`

, ptr is the *pointer operand* and the *result* is `ptr + i`

. According to the quote above, both should point to an element of the array or to one past the last element. That is, in the OP's case `ptr + i`

is a well defined expression for all `i = 0, ..., 10`

. Finally, `*(ptr + i)`

is well defined for `0 <= i < 10`

but not for `i = 10`

.

**Edit**:

I'm puzzled to whether `val[10]`

(or, equivalently, `*(ptr + 10)`

) yields undefined behavior or not (I'm considering C++ not C). In some circumstances this is true (e.g. `int x = val[10];`

is undefined behavior) but in others this is not so clear. For instance,

```
int* p = &val[10];
```

As we have seen, this is equivalent to `int* p = &*(ptr + 10);`

which could be undefined behavior (because it *dereferences* a pointer to one past the last element of `val`

) or the same as `int* p = ptr + 10;`

which is well defined.

I found these two references which show how fuzzy this question is:

May I take the address of the one-past-the-end element of an array?

Take the address of a one-past-the-end array element via subscript: legal by the C++ Standard or not?

isusing it. – Angew Sep 13 '13 at 8:42