std::optional<A> guarantees that no auxiliary memory allocation will take place. This means that the raw buffer for the potential object of type
A is embedded into
std::optional<A>. It is an integral part of
std::optional's memory footprint. This means that the memory size of
std::optional<A> will always be at least
sizeof(A), regardless of whether that optional
A object currently lives or not. That is how much
std::optional<A> will contribute to the total size of
std::unique_ptr<A> is a pointer. Its size is about the same as the size of a regular naked pointer. That is how much memory
std::unique_ptr<A> itself occupies inside
B. In order to make it point to a valid
A object you will have to allocate that
A elsewhere, independently. When
A exists, it occupies memory. When
A does not exist it does not occupy memory.
The above is something to take into account when making your decision.
std::optional<A> does not involve dynamic memory allocation/deallocation, but the price you pay for that is potentially "wasted" memory inside your
std::optional for massively instantiated and/or large objects might prove to be quite wasteful, especially if the object spends most of its lifetime in empty state.
This means that the purpose of
std::optional is not exactly aimed at optional long-term storage.
std::optional is something to be used locally: e.g. as optional local values, optional parameters of functions, optional return values. Long-term use is also OK, as long as you are not instantiating such objects in massive numbers.
std::unique_ptr<A> does not waste memory, but the price you pay for that is dynamic memory allocation/deallocation.
Of course, ownership semantics is also quite different.
std::optional is copyable.
std::unique_ptr is movable, but not copyable.