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is it possible to share two arrays in a union like this:

            float m_V[Height * Length];
            float m_M[Height] [Length];
        } m_U;

Do these two arrays share the same memory size or is one of them longer?

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It's probably not guaranteed by the standard, but in practice this will behave as expected, i.e. the two arrays will be the same size and can be used interchangeably. –  Paul R Jul 9 '12 at 11:09
Small remark: Height and Length have to be compile-time constants. Otherwise it should be okay. –  Jakob S. Jul 9 '12 at 11:13
@PaulR I've actually seen a similar case fail with g++. As long as the accesses are through the union member, g++ recognizes it, but if you pass references to m_V and m_M to a function, I'm less sure. (It might work, because in the end, all of the accesses are to double; in the case I know where it failed, there were different base types involved.) –  James Kanze Jul 9 '12 at 11:23

2 Answers 2

Both arrays are required to have the same size and layout. Of course, if you initialize anything using m_V, then all accesses to m_M are undefined behavior; a compiler might, for example, note that nothing in m_V has changed, and return an earlier value, even though you've modifed the element through m_M. I've actually used a compiler which did so, in the distant past. I would avoid accesses where the union isn't visible, say by passing a reference to m_V and a reference to m_M to the same function.

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I believe that the standard guarantees the access in this case because they are layout compatible. –  David Rodríguez - dribeas Jul 9 '12 at 11:28
@DavidRodríguez-dribeas In C++11, perhaps. I've not studied it in such detail. C++03 didn't have the concept of layout compatibility. (But a quick glance at §3.10 doesn't show any allowance for layout compatibility. There are some fudges for cv-qualifiers and signed/unsigned, but otherwise, the lvalue used to access the object must have either the same type or char or unsigned char. –  James Kanze Jul 9 '12 at 11:40
C++03 9.5p1 If a POD-union contains several POD-structs that share a common initial sequence (9.2), and if an object of this POD-union type contains one of the POD-structs, it is permitted to inspect the common initial sequence of any of POD-struct members. The wording does not mention standard layout types, but it does endorse the usage above. [I am only assuming that an array can be considered a POD-struct, I have not found a definition of POD-struct in the standard] –  David Rodríguez - dribeas Jul 9 '12 at 12:25
@David: float m_V[Height * Length]; and float m_M[Height] [Length]; are not POD structs. They're POD, but they're arrays not structs. They don't share an initial sequence. AFAIK that rule is to allow struct Foo {int type; char *data; }; struct Bar {int type; double *data; }; union FooBar { Foo f; Bar b; }, then you can inspect either of f.type or b.type no matter which of f or b was last assigned. The "common initial sequence" is the int member. –  Steve Jessop Jul 9 '12 at 12:31
@DavidRodríguez-dribeas That's the wording I remember. It is taken directly from the C standard, and is present for reasons of C compatibility. And the traditional interpretation in C is that a common initial sequence means just that: exactly the same types (with, I think, the same names). This is how C implemented polymorphism: the common initial sequence (generally implemented as a macro) represented the base class. And I don't see how it can apply here, since the the union doesn't contain any struct's, much less POD structs. –  James Kanze Jul 9 '12 at 12:32

It is implicitly guaranteed that these will be the same size in memory. The compiler is not allowed to insert padding anywhere in either the 2D array or the 1D array, because everything must be compatible with sizeof.

[Of course, if you wrote to m_V and read from m_M (or vice versa), you'd still be type-punning, which technically invokes undefined behaviour. But that's a different matter.]

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I don't think that would be undefined behavior. The standard is explicit in guaranteeing that access to a member of an union other than the active one is fine if the active member and the accessed member shared a initial compatible layout sequence of members and only those members are accessed. In this case, I believe that the two arrays share an initial sequence of layout compatible sub objects that covers the whole arrays. –  David Rodríguez - dribeas Jul 9 '12 at 11:27
I can't find it at the moment (although I know its there), but at least in C, the compiler was allowed to assume that an lvalue referring to a double [][] did not alias any data in an lvalue referring to a double []. –  James Kanze Jul 9 '12 at 11:44
@JamesKanze: I think the question becomes whether for strict-aliasing purposes I have used an lvalue of type double[][] to "access" the double[] object when I write m_M[0][0] = 0;. If I have, then it's a clear breach of strict aliasing. But when you break down m_M[0][0] I'm not sure that I actually access anything using an lvalue of type double[][] or even double[] - I do form some lvalue expressions with those types, but they decay to pointers. I'm allowed to access members of m_V using an lvalue of type double (the type of m_M[0][0]), no matter how I got there. –  Steve Jessop Jul 9 '12 at 12:39
@SteveJessop My impression is that the original intent was to ban this; the wording in this area is not always very clear, nor necessarily what was intended. In practice, I suspect that most, if not all compilers will treat it as accessing a double in both cases, and assume possible aliasing. –  James Kanze Jul 9 '12 at 16:25
@James Kanze: I believe that one of the TC to C99 actually "legalized" all forms of aliasing, when they are performed through unions specifically. I.e. now you can alias anything to anything through unions, as long as you are not running into trap representations. Trap-representation-related problems are still there, but the compiler is no longer allowed to assume that there's no aliasing there. –  AndreyT Jul 9 '12 at 16:39

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