Several file formats I have read/worked with do exactly that -- define a memory standard or layout, then typically back it up with a demonstration in C-like pseudo-
structure. Sometimes they will provide struct or class representations, and some are completely abstracted by a library. Of course, these formats go on to document all fields, their sizes, the endianness of the data and so on.
I figure endian related issues, padding, complexity (e.g. introduced by variations in the data structures) and proper versioning are the biggest sources of errors. Another issue I find is the use of data structures of yesteryear and inconsistency of data structures used to represent similar functionalities -- You may receive a spec, and realize it contains several different string representations -- all of which are archaic, and somebody has to go on to support all of these (bidirectionally).
Proceeding that route:
You should not commit to a binary representation (or compilable program) if you don't want to support it (and attempts of long-lived formats fail/stumble along the way, as platforms and toolsets change). Just commit to a formal memory standard at first, then build on top of that with tests and example input files to verify the representation is properly serialized and deserialized correctly. A very basic test suite will help ensure your model is portable on all the systems you need, and can point out potential pitfalls or platform specific considerations you may not have been aware of.
If you really want to provide a compilable representation, I'd stick with a very compliant
struct representation -- clients can take that (in memory) representation and turn it into any C++ abstraction/representation they like. That is to say, a serialized representation should probably not reflect that of a representation in memory, apart from trivially simple representations and the intermediate storage of such a representation (flattened and packed structs).
One of the important parts is that you should have tests which confirm your in memory object graph which you create with these structs are forward and backwards serializable and de-serializable, and support proper versioning -- so it often takes a bit of work to make a complex serialized representation compatible. So you see this approach just introduces one abstraction layer on top of another. In this regard, you may want give C++ abstraction the ability to create itself from the packed in memory representation, and to ensure that that representation can also correctly populate the packed structure without data loss.
Beyond that, is there any need to have a more advanced interface? If there is, then you may want to provide that information.
So yes, the memory standard is the part that you must get correct and stable, and to which all implementations should refer to and test against -- regardless of platform/architecture differences. IOW, you're on the right track ;)