The distribution of the sequence of ranked maximum and minimum values attained during excursions of a standard Brownian bridge is described. The height of the $j$th highest maximum $M_j$ over a positive excursion of the bridge has the same distribution as $M_1/j$, where the distribution of $M_1$ is given by L\'evy's formula $P( M_1 > x ) = e^(-2x^2)$. The probability density of the height of the $j$th highest maximum of excursions of the reflecting Brownian bridge is given by a modification of the known $\theta$-function series for the density of the maximum absolute value of the bridge. These results are obtained from a more general description of the distribution of ranked values of a homogeneous functional of excursions of the standardized bridge of a self-similar recurrent Markov process.