int arr[] = { 3, 5, 9, 2, 8, 10, 11 };      
int arrSize = *(&arr + 1) - arr;
std::cout << arrSize;

I am not able to get how this is working. So anyone can help me with this.

  • 27
    This is not a usual idiom. Other readers of the code will be confused as well. Sure, it's a clever trick. Avoid cleverness like the plague.
    – user14215102
    May 12, 2021 at 19:14
  • 16
    Just use std::size May 12, 2021 at 19:15
  • 2
    @ThomasMatthews I was curious, but I dont think we can learn much from this: godbolt.org/z/YdWh8h8YY May 12, 2021 at 19:30
  • 3
    This is the same question but for C: stackoverflow.com/q/56154380/1896169 The C and C++ standards are sufficiently different, however, that it makes sense to have separate questions
    – Justin
    May 13, 2021 at 4:12
  • 8
    FWIW, another alternative is sizeof(arr) / sizeof(arr[0]), IIRC. May 13, 2021 at 17:42

6 Answers 6


If we "draw" the array together with the pointers, it will look something like this:

| arr[0] | arr[1] | ... | arr[6] | ... |
^        ^                       ^
|        |                       |
&arr[0]  &arr[1]                 |
|                                |
&arr                             &arr + 1

The type of the expressions &arr and &arr + 1 is int (*)[7]. If we dereference either of those pointers, we get a value of type int[7], and as with all arrays, it will decay to a pointer to its first element.

So what's happening is that we take the difference between a pointer to the first element of &arr + 1 (the dereference really makes this UB, but will still work with any sane compiler) and a pointer to the first element of &arr.

All pointer arithmetic is done in the base-unit of the pointed-to type, which in this case is int, so the result is the number of int elements between the two addresses being pointed at.

It might be useful to know that an array will naturally decay to a pointer to its first element, ie the expression arr will decay to &arr[0], which will have the type int *.

Also, for any pointer (or array) p and index i, the expression *(p + i) is exactly equal to p[i]. So *(&arr + 1) is really the same as (&arr)[1] (which makes the UB much more visible).

  • Pardon my naivety, but doesn't dereferencing have a higher precedence than subtraction? My understanding of your answer doesn't account for the dereferencing before the subtraction. May 12, 2021 at 19:17
  • For example, the expression &arr + 1 is evaluated first into an address. Next, that address is dereferenced to an integer (i.e. memory is read). Then the address of the array is subtracted from the value read from memory. Am I wrong here? May 12, 2021 at 19:18
  • 2
    @ThomasMatthews Yes, dereference will happen first. Without it, the subtraction wouldn't be possible because the pointers would have unrelated types (int (*)[7] and int *). Dereferencing (&arr + 1) produces a value of type int [7], which then decays to int *, making the pointer types the same. The dereference here merely changes the pointer type, and not its numerical value. May 12, 2021 at 19:19
  • 2
    @AyxanHaqverdili Remember that expressions can't have reference types. eel.is/c++draft/expr#type-1 And decltype adds fake & and && to types of expressions to indicate value categories of those expressions (for lvalues and xvalues respectively; types of prvalues are unchanged). May 12, 2021 at 19:25
  • 1
    @AyxanHaqverdili decltype has special rules for variables. For them it returns the type that's written next to them. If you do decltype((a)), it will return int & (because unlike a, decltype doesn't consider (a) a variable, so the regular rules apply). May 12, 2021 at 19:34

That program has undefined behaviour. (&arr + 1) is a valid pointer that points "one beyond" arr, and has type int(*)[7], however it doesn't point to an int [7], so dereferencing it is invalid.

It so happens that your implementation assumes there is a second int [7] after the one you declare, and subtracts the location of the first element of that array that exists from the location of the first element of the fictitious array that the pointer arithmetic invented.

  • 13
    I'm not sure this is definitely UB. I asked a related question (Dereferencing one past the end pointer to array type) and the answer to "is it legal" seems to be "it's an active core language issue". Edit : it still shouldn't be used, as it is also not definitely allowed yet. May 12, 2021 at 19:15
  • 2
    @FrançoisAndrieux clang thinks it's UB, GCC and MSVC think it's not godbolt.org/z/r4e14e9MG May 12, 2021 at 19:56
  • 3
    @AyxanHaqverdili: clang doesn't accept it as constexpr, but compiles it ok with return .... godbolt.org/z/r96YhWEe1 - With -fsanitize=undefined, clang makes asm that checks if the stack pointer is within 28 bytes of the top of virtual address space, so it's checking for pointer overflow. (It of course runs fine). That may be a sign that it doesn't "understand" / "accept" what's going on; it just wrote that memory so the pointer's definitely valid if it didn't crash. So probably it doesn't realize that it's just doing 1-past-end of a valid object. May 13, 2021 at 3:33
  • 3
    @PeterCordes Interesting analysis. The standard requires compilers to check for undefined behavior in constexpr. I used constexpr there to "get compilers' opinions" so to speak :) May 13, 2021 at 8:21
  • 1
    No +1 as you lack an explanation why it's UB. I, too, think that it's UB however: stackoverflow.com/q/39401136/1116364 May 13, 2021 at 11:40

You need to explore what the type of the &arr expression is, and how that affects the + 1 operation on it.

Pointer arithmetic works in 'raw units' of the pointed-to type; &arr is the address of your array, so it points to an object of type, "array of 7 int". Adding 1 to that pointer actually adds the size of the type to the address – so 7 * sizeof(int) is added to the address.

However, in the outer expression (subtraction of arr), the operands are pointers to int objects1 (not arrays), so the 'units' are just sizeof(int) – which is 7 times smaller than in the inner expression. Thus, the subtraction results in the size of the array.

1 This is because, in such expressions, an array variable (such as the second operand, arr) decays to a pointer to its first element; further, your first operand is also an array, as the * operator dereferences the modified value of the array pointer.

Note on Possible UB: Other answers (and comments thereto) have suggested that the dereferencing operation, *(&arr + 1), invokes undefined behaviour. However, looking through this Draft C++17 Standard, there is the vaguest of suggestions that it may not:

6.7.2 Compound Types
3    … For purposes of pointer arithmetic (8.5.6) and comparison (8.5.9, 8.5.10), a pointer past the end of the last element of an array x of n elements is considered to be equivalent to a pointer to a hypothetical element x[n].

But I won't claim "Language-Lawyer" status here, as there is no explicit mention in that section about dereferencing such a pointer.

  • 1
    Did you account for the deferencing of the expression &arr - 1? May 12, 2021 at 19:20
  • @ThomasMatthews Where does that expression occur in the posted code? May 12, 2021 at 19:21
  • 1
    Sorry, my bad. It was supposed to be &arr + 1. May 12, 2021 at 19:23
  • @ThomasMatthews No problem - see edit. (Thanks for suggesting, BTW.) May 12, 2021 at 19:24
  • 1
    I won't consider that section of the standard vaguely supporting it. It clearly says "purposes of pointer arithmetic and comparison". This means that x[n] can be freely compared or subtracted with any other element in the array. Not more, not less.
    – IS4
    May 13, 2021 at 9:24

If you have a declaration like this

int arr[] = { 3, 5, 9, 2, 8, 10, 11 };

the the expression &arr + 1 will point to the memory after the last element of the array. The value of the expression is equal to the value of the expression arr + 7 where 7 is the number of elements in the array declared above. The only difference is that the expression &arr + 1 has the type int ( * )[7] while the expression arr + 7 has the type int *.

So due to the integer arithmetic the difference ( arr + 7 ) - arr will yield 7: the number of elements in the array.

On the other hand, dereferencing the expression &att + 1 having the type int ( * )[7] we will get lvalue of the type int[7] that in turn used in the expression *(&arr + 1) - arr is converted to a pointer of the type int * and has the same value as arr + 7 as it was pointed out above. So the expression will yield the number of elements in the array.

The only difference between these two expressions

( arr + 7 ) - arr


*( &arr + 1 ) - arr

is that in the first case we will need explicitly to specify the number of elements in the array to get the address of the memory after the last element of the array while in the second case the compiler itself will calculate the address of the memory after the last element of the array knowing the array declaration.


As others have mentioned, *(&arr + 1) triggers undefined behavior because &arr + 1 is a pointer to one-past-the end of an array of type int [7] and that pointer is subsequently dereferenced.

An alternate way of doing this would be to convert the relevant pointers to uintptr_t, subtracting, and dividing the element size.

int arrSize = reinterpret_cast<int>((reinterpret_cast<uintptr_t>(&arr + 1) -
                                     reinterpret_cast<uintptr_t>(arr)) / sizeof *arr);

Or using C-style casts:

int arrSize = (int)(((uintptr_t)(&arr + 1) - (uintptr_t)arr) / sizeof *arr);
  • Wouldn't ptrdiff_t be better here than uintptr_t? May 12, 2021 at 19:34
  • @AdrianMole Only for the result type instead of int. I think it could overflow/underflow if you try to subtract it. May 12, 2021 at 19:43
  • 1
    timsong-cpp.github.io/cppwp/expr.reinterpret.cast#5 : "mappings between pointers and integers are otherwise implementation-defined." so this solution can work, it likely works on most implementation, but is not portable. You very well could have an implementation where, for example (uintptr_t)&arr[0] is bigger than (uintptr_t)&arr[1]. May 12, 2021 at 19:49

This one is simple:

  1. arr is just a pointer to the 0'th element of the array (&arr[0]);
  2. &arr gives a pointer to the previous pointer;
  3. &arr+1 gives a pointer to a pointer to arr[0]+sizeof(arr)*1;
  4. *(&arr + 1) turns the previous value into just &arr[0]+sizeof(arr)*1;
  5. *(&arr + 1) - arr also subtracts the pointer to arr[0] leaving just sizeof(arr)*1.

So the only tricks here are that static arrays in C internally preserve all their static type information including their total sizes and that when you increment a pointer by some integer value, C compilers don't just add the value to it, but for whatever reason standards require to increase the pointers by the value of sizeof() of whatever type the pointer is assigned to times the specified value so *(&p+idx) gives the same result as p[idx].

C language is designed to allow for very simplistic compilers so inside it is full of little tricks like this. I would not recommend using them in production code though. Remember about other developers who may need to read and maintain your code later and use the most simple and obvious stuff available instead (for the example it is obviously just using sizeof() directly).

  • 1
    arr is an array, not a pointer. Arrays can decay to pointers to their first elements in many cases, but this is not one of those cases. Consequently, &arr, is not a pointer-to-pointer (not int **), but, as 3 other answers have stated, a pointer-to-array (int (*)[7]). May 14, 2021 at 18:58
  • Also step 4 is slightly confusing, since &arr[0]+sizeof(arr)*1 would additionally multiply the rhs by sizeof(int). May 14, 2021 at 19:01
  • In C for static arrays the only difference with pointers is the fact that it has some metadata associated with it which we can ignore for all the cases except for the hidden sizeof() which always gives the total size of the array in bytes, not just the number of its elements. So I don't see any confusion here. For dynamic arrays there is absolutely no difference with pointers at all except for the syntax.
    – mrKirushko
    May 15, 2021 at 18:08
  • Let's ignore "dynamic arrays" for now, since it's just a name for regular pointers pointing to dynamically allocated memory. "only difference with pointers is the fact that it has some metadata associated" It's a way to think about arrays I guess, but this interpretation breaks under scrutiny. A (static) array is not a pointer (with or without metadata). When an array is converted to a pointer, the resulting pointer is computed on the fly, in general it's not stored in the memory otherwise. May 15, 2021 at 20:44
  • If you use your debugger to inspect the memory associated with an array, you'll find no pointer there. Mext, if you make a pointer-to-pointer (int **) and try to point it to an array, the compiler won't let you - again, because arrays don't store pointers to their elements. "has some metadata associated" There's no hidden metadata involved. They just have different types compared to pointers. They are implicitly converted to pointers in many cases, but not always. That doesn't happen are applying sizeof, yes, but also when applying and & to it, or binding it to a reference. May 15, 2021 at 20:50

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