I'm going to build a custom allocator, preallocating a big block (array) for storing
N elements of some class
T, and then just increase an index inside the array to service allocation requests.
Since I don't want any initialization for the elements in the pre-allocated block, something like this won't work:
because in this case
T's constructor will be called for the
N elements of the block.
Since my understanding is that
std::aligned_storage doesn't call
T's constructor, I thought of using
std::aligned_storage, something like this:
std::aligned_storage< N * sizeof(T), std::alignment_of<T>::value >::type buffer; T* base = static_cast<T*>( static_cast<void*>(&buffer) );
And then the allocator can just increment the base pointer when an allocation for a T is requested (until
(base+N)), and T can be constructed in place (with placement
new) when needed.
I'd like to use this scheme to define a custom allocator for STL containers. However, it seems to me that there could be a problem here for rebinding. In fact, if my understanding is correct, an STL allocator should support rebinding from a type
T to a type
U, e.g. because containers like
std::list<T> (or other node-based containers like
std::map) use allocators to allocate nodes that are not actually of type
T, but of different type
T and other "header" overhead information for the node).
So, would the aforementioned
std::aligned_storage approach work well for rebinding? Or (as I think) a correct alignment for
Ts does not imply a correct alignment for another different type
How could this problem be solved?
How could I define the aforementioned
buffer to make it work also for rebinding to some different type
Should this problem be attacked from a different perspective? If so, what?