SOME_THRESHOLD is constant, then you've hard coded a constant upper bound on the growth of the function (and
f(x) = O (g(x)) gives an upper bound of
g(x) on the growth of
O(k) for some constant
k is just
O(1) because we don't care about constant factors.
Note that the lower bound is unknown, a least theoretically, because we don't know anything about the lower bound of the
O(n^2) function. We know that for
f(x) = Omega(h(x)),
h(x) <= 1 because
f(x) = O(1). Less than constant-time functions are possible in theory, although in practice
h(x) = 1, so
f(x) = Omega(1).
What all this means is by forcing a constant upper bound on the function, the function now has a tight bound:
f(x) = Theta(1).