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Taking into consideration the entire C++11 standard, is it possible for any conforming implementation to succeed the first assertion below but fail the latter?

#include <cassert>

int main(int, char**)
    const int I = 5, J = 4, K = 3;
    const int N = I * J * K;

    int arr1d[N] = {0};
    int (&arr3d)[I][J][K] = reinterpret_cast<int (&)[I][J][K]>(arr1d);
    assert(static_cast<void*>(arr1d) ==
           static_cast<void*>(arr3d)); // is this necessary?

    arr3d[3][2][1] = 1;
    assert(arr1d[3 * (J * K) + 2 * K + 1] == 1); // UB?

If not, is this technically UB or not, and does that answer change if the first assertion is removed (is reinterpret_cast guaranteed to preserve addresses here?)? Also, what if the reshaping is done in the opposite direction (3d to 1d) or from a 6x35 array to a 10x21 array?

EDIT: If the answer is that this is UB because of the reinterpret_cast, is there some other strictly compliant way of reshaping (e.g., via static_cast to/from an intermediate void *)?

share|improve this question
Very interesting question, and I think it may be possible to do this without UB, thanks to "layout-compatible" types, although I'm not sure if those only apply to structs / classes - will have to investigatte. – Xeo Mar 7 '13 at 23:06
I'm pretty sure the C++11 spec guarantees this behavior actually. – Mooing Duck Mar 7 '13 at 23:06
Well, do I need to check the first assertion then, or not? Are the addresses guaranteed to be equal? – Stephen Lin Mar 7 '13 at 23:07
yeah, but this is casting between references to two different array types – Stephen Lin Mar 7 '13 at 23:15
@MooingDuck: We're not comparing the address of array to its converted pointer here. – Xeo Mar 7 '13 at 23:15
up vote 20 down vote accepted

reinterpret_cast of references

The standard states that an lvalue of type T1 can be reinterpret_cast to a reference to T2 if a pointer to T1 can be reinterpret_cast to a pointer to T2 (§5.2.10/11):

An lvalue expression of type T1 can be cast to the type “reference to T2” if an expression of type “pointer to T1” can be explicitly converted to the type “pointer to T2” using a reinterpret_cast.

So we need to determine if a int(*)[N] can be converted to an int(*)[I][J][K].

reinterpret_cast of pointers

A pointer to T1 can be reinterpret_cast to a pointer to T2 if both T1 and T2 are standard-layout types and T2 has no stricter alignment requirements than T1 (§5.2.10/7):

When a prvalue v of type “pointer to T1” is converted to the type “pointer to cv T2”, the result is static_cast<cv T2*>(static_cast<cv void*>(v)) if both T1 and T2 are standard-layout types (3.9) and the alignment requirements of T2 are no stricter than those of T1, or if either type is void.

  1. Are int[N] and int[I][J][K] standard-layout types?

    int is a scalar type and arrays of scalar types are considered to be standard-layout types (§3.9/9).

    Scalar types, standard-layout class types (Clause 9), arrays of such types and cv-qualified versions of these types (3.9.3) are collectively called standard-layout types.

  2. Does int[I][J][K] have no stricter alignment requirements than int[N].

    The result of the alignof operator gives the alignment requirement of a complete object type (§3.11/2).

    The result of the alignof operator reflects the alignment requirement of the type in the complete-object case.

    Since the two arrays here are not subobjects of any other object, they are complete objects. Applying alignof to an array gives the alignment requirement of the element type (§5.3.6/3):

    When alignof is applied to an array type, the result shall be the alignment of the element type.

    So both array types have the same alignment requirement.

That makes the reinterpret_cast valid and equivalent to:

int (&arr3d)[I][J][K] = *reinterpret_cast<int (*)[I][J][K]>(&arr1d);

where * and & are the built-in operators, which is then equivalent to:

int (&arr3d)[I][J][K] = *static_cast<int (*)[I][J][K]>(static_cast<void*>(&arr1d));

static_cast through void*

The static_cast to void* is allowed by the standard conversions (§4.10/2):

A prvalue of type “pointer to cv T,” where T is an object type, can be converted to a prvalue of type “pointer to cv void”. The result of converting a “pointer to cv T” to a “pointer to cv void” points to the start of the storage location where the object of type T resides, as if the object is a most derived object (1.8) of type T (that is, not a base class subobject).

The static_cast to int(*)[I][J][K] is then allowed (§5.2.9/13):

A prvalue of type “pointer to cv1 void” can be converted to a prvalue of type “pointer to cv2 T,” where T is an object type and cv2 is the same cv-qualification as, or greater cv-qualification than, cv1.

So the cast is fine! But are we okay to access objects through the new array reference?

Accessing array elements

Performing array subscripting on an array like arr3d[E2] is equivalent to *((E1)+(E2)) (§5.2.1/1). Let's consider the following array subscripting:


Firstly, arr3d[3] is equivalent to *((arr3d)+(3)). The lvalue arr3d undergoes array-to-pointer conversion to give a int(*)[2][1]. There is no requirement that the underlying array must be of the correct type to do this conversion. The pointers value is then accessed (which is fine by §3.10) and then the value 3 is added to it. This pointer arithmetic is also fine (§5.7/5):

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.

This this pointer is dereferenced to give an int[2][1]. This undergoes the same process for the next two subscripts, resulting in the final int lvalue at the appropriate array index. It is an lvalue due to the result of * (§5.3.1/1):

The unary * operator performs indirection: the expression to which it is applied shall be a pointer to an object type, or a pointer to a function type and the result is an lvalue referring to the object or function to which the expression points.

It is then perfectly fine to access the actual int object through this lvalue because the lvalue is of type int too (§3.10/10):

If a program attempts to access the stored value of an object through a glvalue of other than one of the following types the behavior is undefined:

  • the dynamic type of the object
  • [...]

So unless I've missed something. I'd say this program is well-defined.

share|improve this answer
+1 for standard quotes, have to think about your answer though – Stephen Lin Mar 8 '13 at 0:00
this was helpful, had no idea reinterpret_cast was actually ok in this case; everything sounds good to me – Stephen Lin Mar 8 '13 at 0:13

I am under the impression that it will work. You allocate the same piece of contiguous memory. I know the C-standard guarantees it will be contiguous at least. I don't know what is said in the C++11 standard.

However the first assert should always be true. The address of the first element of the array will always be the same. All memory address will be the same since the same piece of memory is allocated.

I would therefore also say that the second assert will always hold true. At least as long as the ordering of the elements are always in row major order. This is also guaranteed by the C-standard and I would be surprised if the C++11 standard says anything differently.

share|improve this answer
"Taking into consideration the entire C++11 standard," – Mooing Duck Mar 7 '13 at 23:12
is the behavior of reinterpret_cast guaranteed in this case, though? these are technically incompatible types – Stephen Lin Mar 7 '13 at 23:12
@StephenLin "The result is a pointer to the first element of the array" So the 1d becomes a pointer to the first int. The 3d becomes a pointer to the first 2d array, which becomes a pointer to the first 1d array, which becomes a pointer to the first int. The same first int. – Mooing Duck Mar 7 '13 at 23:15
@AxelOmega: I'm not certain "row-major" is the right term for a 3d array. – Mooing Duck Mar 7 '13 at 23:16
@Xeo, I think to/from void * has some special guarantees on preserving addresses, I might be wrong; I don't think reinterpret_cast to/from incompatible arrays does, though, which is why I wrote it this way – Stephen Lin Mar 7 '13 at 23:19

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