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
?


Complexity of Linear complexity in the average case. N^{2} in the worst case, where N is the size of the container. More details in the standard §23.2.5, point 11: For 


The very worst case is O(n²). But unordered sets are in fact ordered by hash. So it is possible to compare the hashes (if this fails the sets cannot be equal) and then verify that same hashes (linear) have real same values (O(n²) for different values with the same hash) behind. In the best case this is O(n). Normally the complexity tends to O(n) if the hash function is "good" (different objects > always different hash) and to O(n²) if the hash function is "bad" (everything always has the same hash value) 


a
andb
compare equal ifa.size() == b.size()
and, for every equivalentkey group[Ea1,Ea2)
obtained froma.equal_range(Ea1)
, there exists an equivalentkey group[Eb1,Eb2)
obtained fromb.equal_range(Ea1)
, such thatdistance(Ea1, Ea2) == distance(Eb1, Eb2)
andis_permutation(Ea1, Ea2, Eb1)
returnstrue
. Forunordered_set
...the complexity ofoperator==
...is proportional toN
in the average case and toN^2
in the worst case, whereN
isa.size()
." – James McNellis Apr 12 '12 at 6:40