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Can you propose at least 1 scenario where there is a substantial difference between

union {
T var_1;
U var_2;


var_2 = reinterpret_cast<U> (var_1)


The more i think about this, the more they look like the same thing to me, at least from a practical viewpoint.

One difference that I found is that while the union size is big as the biggest data type in terms of size, the reinterpret_cast as described in this post can lead to a truncation, so the plain old C-style union is even safer than a newer C++ casting.

Can you outline the differences between this 2 ?

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As far as I know, using unions for type punning is safe in C - I'm not sure about C++, maybe it is not, and then you must use typecasting. –  user529758 Jul 29 '13 at 12:18
@H2CO3 I don't know (and honestly don't care) if using unions is safe, but reinterpret_cast is strictly not safer. –  R. Martinho Fernandes Jul 29 '13 at 12:19
@user2485710 because 1) who the hell needs this; and 2) memcpy works perfectly fine for this, with no need to pick weasel interpretations of the standard to make it work. –  R. Martinho Fernandes Jul 29 '13 at 12:22
@R.MartinhoFernandes: To answer your question, "who the hell needs this," I do. –  John Dibling Jul 29 '13 at 12:29
@user2485710: sizeof works in terms of bytes because all object sizes are a multiple of a byte. End of story. Now could you please stop this pointless argument. –  Mike Seymour Jul 29 '13 at 12:48

4 Answers 4

up vote 6 down vote accepted

Contrary to what the other answers state, from a practical point of view there is a huge difference, although there might not be such a difference in the standard.

From the standard point of view, reinterpret_cast is only guaranteed to work for roundtrip conversions and only if the alignment requirements of the intermediate pointer type are not stronger than those of the source type. You are not allowed (*) to read through one pointer and read from another pointer type.

At the same time, the standard requires similar behavior from unions, it is undefined behavior to read out of a union member other than the active one (the member that was last written to)(+).

Yet compilers often provide additional guarantees for the union case, and all compilers I know of (VS, g++, clang++, xlC_r, intel, Solaris CC) guarantee that you can read out of an union through an inactive member and that it will produce a value with exactly the same bits set as those that were written through the active member.

This is particularly important with high optimizations when reading from network:

double ntohdouble(const char *buffer) {          // [1]
   union {
      int64_t   i;
      double    f;
   } data;
   memcpy(&data.i, buffer, sizeof(int64_t));
   data.i = ntohll(data.i);
   return data.f;
double ntohdouble(const char *buffer) {          // [2]
   int64_t data;
   double  dbl;
   memcpy(&data, buffer, sizeof(int64_t));
   data = ntohll(data);
   dbl = *reinterpret_cast<double*>(&data);
   return dbl;

The implementation in [1] is sanctioned by all compilers I know (gcc, clang, VS, sun, ibm, hp), while the implementation in [2] is not and will fail horribly in some of them when aggressive optimizations are used. In particular, I have seen gcc reorder the instructions and read into the dbl variable before evaluating ntohl, thus producing the wrong results.

(*) With the exception that you are always allowed to read from a [signed|unsigned] char* regardless of that the real object (original pointer type) was.

(+) Again with some exceptions, if the active member shares a common prefix with another member, you can read through the compatible member that prefix.

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Interesting. The failure in the reinterpret_cast-implementation surprises me. Can this be considered a bug or is the standard simply too strict to use the cast for such applications? I am not familiar with networking in C++. –  Marc Claesen Jul 29 '13 at 15:13
@MarcClaesen: Google for strict aliasing and some blunt word and you will find someone complaining on that behavior in GCC. The standard provides a set of situations for valid aliasing (multiple pointers referring to the same object), outside of the limited set, everything else is undefined behavior, and the case of the reinterpret_cast above is undefined behavior. For more info, google 'strict aliasing', 'no-strict-aliasing' or something alike –  David Rodríguez - dribeas Jul 29 '13 at 15:46

There are some technical differences between a proper union and a (let's assume) a proper and safe reinterpret_cast. However, I can't think of any of these differences which cannot be overcome.

The real reason to prefer a union over reinterpret_cast in my opinion isn't a technical one. It's for documentation.

Supposing you are designing a bunch of classes to represent a wire protocol (which I guess is the most common reason to use type-punning in the first place), and that wire protocol consists of many messages, submessages and fields. If some of those fields are common, such as msg type, seq#, etc, using a union simplifies tying these elements together and helps to document exactly how the protocol appears on the wire.

Using reinterpret_cast does the same thing, obviously, but in order to really know what's going on you have to examine the code that advances from one packet to the next. Using a union you can just take a look at the header and get an idea what's going on.

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What alignment issues would arise in an union? –  R. Martinho Fernandes Jul 29 '13 at 12:40
@R.MartinhoFernandes: Until I can think of a good answer to your question, I'm going to remove that bit from my answer. –  John Dibling Jul 29 '13 at 12:46
Fair enough. FWIW I believe you got it the wrong way around: alignment in a union is guaranteed right by the compiler, while reinterpret_cast to a type with a more strict alignment is dangerous. –  R. Martinho Fernandes Jul 29 '13 at 12:47
@R.MartinhoFernandes: No, I know. –  John Dibling Jul 29 '13 at 12:49
Since no "relevant" differences are popping out at this point, I'm going to accept this answer to prevent this question going really OT or on the metaphysics side . –  user2485710 Jul 29 '13 at 12:52

In C++11, union is class type, you can an hold a member with non-trial member functions. You can't simply cast from one member to another.

§ 9.5.3

[ Example: Consider the following union:

union U {
int i;
float f;
std::string s;

Since std::string (21.3) declares non-trivial versions of all of the special member functions, U will have an implicitly deleted default constructor, copy/move constructor, copy/move assignment operator, and de- structor. To use U, some or all of these member functions must be user-provided. — end example ]

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ok, what if I decide that T and U are just POD types ? In that case, considering your answer, you are basically saying that they are the same, right ? –  user2485710 Jul 29 '13 at 12:25
You might add that unions are indeed classes that contain objects of different types at different times, which is something fundamentally different than reinterpreting types. –  cli_hlt Jul 29 '13 at 12:25
@user2485710: It doesn't matter if they're POD types or not; as far as C++ is concerned, this is either implementation-defined behavior or undefined behavior. Unions only make sense to C++ if you access the variable you stored into them. C++ does not have a standard-protected mechanism for in-place type punning. –  Nicol Bolas Jul 29 '13 at 12:29

From a practical point of view, they're most probably 100% identical, at least on real, non-fictional computers. You take the binary representation of one type and stuff it into another type.

From a language lawyer point of view, using reinterpret_cast is well-defined for some occasions (e.g. pointer to integer conversions) and implementation-specific otherwise.

Union type punning, on the other hand is very clearly undefined behaviour, always (though undefined does not necessarily mean "doesn't work"). The standard says that the value of at most one of the non-static data members can be stored in a union at any time. This means that if you set var1 then var1 is valid, but var2 is not.
However, since var1 and var2 are stored at the same memory location, you can of course still read and write any of the types as you like, and assuming they have the same storage size, no bits are "lost".

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It's not just about computers. It's about compilers as well. –  R. Martinho Fernandes Jul 29 '13 at 12:37

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