The math being done here is as follows. When you say O(n(n + n^{2})), that's equivalent to saying O(n^{2} + n^{3}) by simply distributing the n throughout the product.

The reason that O(n^{2} + n^{3}) = O(n^{3}) follows from the formal definition of big-O notation, which is as follows:

A function f(n) = O(g(n)) iff there exists constants n_{0} and c such that for any n ≥ n_{0}, |f(n)| ≤ c|g(n)|.

Informally, this says that as n gets arbitrary large, f(n) is bounded from above by a constant multiple of g(n).

To formally prove that n^{2} + n^{3} is O(n^{3}), consider any n ≥ 1. Then we have that

n^{2} + n^{3} ≤ n^{3} + n^{3} = 2n^{3}

So we have that n^{2} + n^{3} = O(n^{3}), with n_{0} = 1 and c = 2. Consequently, we have that

O(n(n + n^{2})) = O(n^{2} + n^{3}) = O(n^{3}).

To be truly formal about this, we would need to show that if f(n) = O(g(n)) and g(n) = O(h(n)), then f(n) = O(h(n)). Let's walk through a proof of this. If f(n) = O(g(n)), there are constants n_{0} and c such that for n ≥ n_{0}, |f(n)| ≤ c|g(n)|. Similarly, since g(n) = O(h(n)), there are constants n'_{0}, c' such that for n ≥ n'_{0}, g(n) ≤ c'|h(n)|. So this means that for any n ≥ max(c, c'), we have that

|f(n)| ≤ c|g(n)| ≤ c|c'h(n)| = c x c' |h(n)|

And so f(n) = O(h(n)).

To be a bit more precise - in the case of the algorithm described here, the authors are saying that the runtime is Θ(n^{3}), which is a stronger result than saying that the runtime is O(n^{3}). Θ notation indicates a tight asymptotic bound, meaning that the runtime grows at the same rate as n^{3}, not just that it is bounded from above by some multiple of n^{3}. To prove this, you would also need to show that n^{3} is O(n^{2} + n^{3}). I'll leave this as an exercise to the reader. :-)

More generally, if you have *any* polynomial of order k, that polynomial is O(n^{k}) using a similar argument. To see this, let P(n) = ∑_{i=0}^{k}(a_{i}n^{i}). Then, for any n ≥ 1, we have that

∑_{i=0}^{k}(a_{i}n^{i}) ≤ ∑_{i=0}^{k}(a_{i}n^{k}) = (∑_{i=0}^{k}(a_{i}))n^{k}

so P(n) = O(n^{k}).

Hope this helps!