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 (libstdc++, source in `bits/stl_vector.h`

) 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 in `bits/stl_construct.h`

, 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 `std::_Destroy(ptr)`

.

The trick comes on line 126:

```
std::_Destroy_aux<__has_trivial_destructor(_Value_type)>::
__destroy(__first, __last);
```

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 `int`

, `double`

, and other POD types.

The `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 `clear`

to `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.