While obtaining optimal algorithms for the most important problems in the LOCAL model has been one of the central goals in the area of distributed algorithms since its infancy, tight complexity bounds are elusive for many problems even when considering \emph{deterministic} complexities on \emph{trees}. We take a step towards remedying this issue by providing a way to relate the complexity of a problem $Π$ on trees to its truly local complexity, which is the (asymptotically) smallest function $f$ such that $Π$ can be solved in $O(f(Δ)+\log^*n)$ rounds. More specifically, we develop a transformation that takes an algorithm $\mathcal A$ for $Π$ with a runtime of $O(f(Δ)+\log^*n)$ rounds as input and transforms it into an $O(f(g(n))+\log^* n)$-round algorithm $\mathcal{A}'$ on trees, where $g$ is the function that satisfies $g(n)^{f(g(n))}=n$. If $f$ is the truly local complexity of $Π$ (i.e., if $\mathcal{A}$ is asymptotically optimal), then $\mathcal{A}'$ is an asymptotically optimal algorithm on trees, conditioned on a natural assumption on the nature of the worst-case instances of $Π$. Our transformation works for any member of a wide class of problems, including the most important symmetry-breaking problems. As an example of our transformation we obtain the first strongly sublogarithmic algorithm for $(\text{edge-degree+1})$-edge coloring (and therefore also $(2Δ-1)$-edge coloring) on trees, exhibiting a runtime of $O(\log^{12/13} n)$ rounds. This breaks through the $Ω(\log n/\log\log n)$-barrier that is a fundamental lower bound for other symmetry-breaking problems such as maximal independent set or maximal matching (that already holds on trees), and proves a separation between these problems and the aforementioned edge coloring problems on trees. We extend a subset of our results to graphs of bounded arboricity.

To appear at PODC 2025