# How expensive is comparing two unordered sets for equality?

Given two `std::set`s, one can simply iterate through both sets simultaneously and compare the elements, resulting in linear complexity. This doesn't work for `std::unordered_set`s, because the elements may be stored in any order. So how expensive is `a == b` for `std::unordered_set`?

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Do you have an efficient way to check set membership (for example are they backed by hashtables)? –  Thilo Apr 12 '12 at 6:36
In the clear, straightforward, easy to comprehend and understand words of the C++ Standard: "Two unordered containers `a` and `b` compare equal if `a.size() == b.size()` and, for every equivalent-key group `[Ea1,Ea2)` obtained from `a.equal_range(Ea1)`, there exists an equivalent-key group `[Eb1,Eb2)` obtained from `b.equal_range(Ea1)`, such that `distance(Ea1, Ea2) == distance(Eb1, Eb2)` and `is_permutation(Ea1, Ea2, Eb1)` returns `true`. For `unordered_set`...the complexity of `operator==`...is proportional to `N` in the average case and to `N^2` in the worst case, where `N` is `a.size()`." –  James McNellis Apr 12 '12 at 6:40

Complexity of `operator==` and `operator!=`:

Linear complexity in the average case. N2 in the worst case, where N is the size of the container.

More details in the standard §23.2.5, point 11:

For `unordered_set` and `unordered_map`, the complexity of `operator==` (i.e., the number of calls to the `==` operator of the `value_type`, to the predicate returned by `key_equal()`, and to the hasher returned by `hash_function()`) is proportional to `N` in the average case and to N2 in the worst case, where `N` is `a.size()`.

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