Let us consider the projective line over $\mathbb C$ equipped with a nice metric $\eta$ (like the Fubini-Study metric). We can define a metric $\mu$ on rational functions $f: \mathbb P^1 \to \mathbb P^1$ by: $$\mu(f,g) = \sup_{x \in \mathbb P^1}\eta(f(x),g(x)).$$ What can we say about $\mathbb C(t)$ as a metric space with respect to $\mu$? Is it complete? Can we classify the convergent sequences? Is this sort of construction studied more generally? Are nice conditions known for which the resulting metric space on endomorphisms is complete?

As a concrete example, if $f_n(x) = a_nx$ for $a_n \in \mathbb R$, then I believe: $$\mu(f_n,f_m) = \frac{\pi}{2} - 2\tan^{-1}\left(\sqrt{\frac{a_n}{a_m}}\right).$$ In particular, if $a_n$ converges to a non zero limit, then so does $f_n$.