It seems the best thing to do would be to set the vector size to 0, so that the complexity is constant.
In general, the complexity of resizing a vector to zero is linear in the number of elements currently stored in the
vector. Therefore, setting
vector's size to zero offers no advantage over calling
clear() - the two are essentially the same.
However, at least one implementation (the source of which is at this link) gives you an O(1) complexity for primitive types by employing partial template specialization.
The implementation of
clear() navigates its way to the
std::_Destroy(from, to) function, which performs a non-trivial compile-time optimization: it declares an auxiliary template class
_Destroy_aux with the template parameter of type
bool. The class has a partial specialization for
true and an explicit specialization for
false. Both specializations define a single static function called
__destroy. In case the template parameter is
true, the function body is empty; in case the parameter is
false, the body contains a loop invoking
T's destructor by calling
The trick comes on line 128:
The auxiliary class is instantiated based on the result of the
__has_trivial_destructor check. The checker returns
true for built-in types, and
false for types with non-trivial destructor. As the result, the call to
__destroy becomes a no-op for
double, and other POD types.
std::unordered_map is different from the
vector in that it may need to delete structures that represent "hash buckets" of POD objects, as opposed to deleting objects themselves*. The optimization of
O(1) is possible, but it is heavily dependent on the implementation, so I would not count on it.
* The exact answer depends on the implementation: hash tables implementing collision resolution based on open addressing (linear probing, quadratic probing, etc.) may be able to delete all buckets in
O(1); implementations based on separate chaining would have to delete buckets one-by-one, though.