As far as I can tell, the requirements on an allocator to be used with STL containers are laid out in Table 28 of section 184.108.40.206 of the C++11 standard.
I'm a bit confused about the interaction between some of these requirements.
Given a type
X that is an allocator for type
T, a type
Y that is "the
corresponding allocator class" for type
X, and an instance
Y, the table says:
a1 == a2evaluates to
trueonly if storage allocated from
a1can be deallocated by
a2, and vice versa.
X a1(a);is well-formed, doesn't exit via an exception, and afterward
a1 == ais true.
X a(b)is well-formed, doesn't exit via an exception, and afterward
a == b.
I read this as saying that all allocators must be copy-constructible in such a way that the copies are interchangeable with the originals. Worse, the same true across type boundaries. This seems to be a pretty onerous requirement; as far as I can tell, it makes impossible a large number of types of allocators.
For example, say I had a freelist class that I wanted to use in my allocator,
in order to cache freed objects. Unless I'm missing something, I couldn't
include an instance of that class in the allocator, because the sizes or
U might differ and therefore the freelist entries are
Are my interpretations above correct?
I've read in a few places that C++11 improved support for "stateful allocators". How is that the case, given these restrictions?
Do you have any suggestions for how to do the sort of thing I'm trying to do? That is, how do I include allocated-type-specific state in my allocator?
In general, the language around allocators seems sloppy. (For example, the prologue to Table 28 says to assume that
ais of type
X&, but some of the expressions redefine
a.) Also, at least GCC's support is non-conformant. What accounts for this weirdness around allocators? Is it just an infrequently used feature?