Rain falls steadily on an island, a 2-manifold $M$, which you may assume, as you prefer, is: (a) smooth, or (b) a PL-manifold, or perhaps even (c) a <a href="http://en.wikipedia.org/wiki/Triangulated_irregular_network">triangulated irregular network (TIN)</a>. After a time, $M$ is saturated, in the sense that every raindrop drains into the ocean rather than filling yet-unfilled crevices or basins. At this point, we have what I will dub the _rain hull_ of $M$, $H_R(M)$, a uni-directional version of the the reflex-free hull, explored (by Bill Thurston) in <a href="http://mathoverflow.net/questions/39378/">this MO question</a>. <b>Q1.</b> How difficult is to compute the rain hull $H_R(M)$? My sense is that it might be quite difficult, because it seems there can be nonlocal influences, as crudely depicted (not necessarily physically accurately) in this side-view schematic: <br /> <img src="http://cs.smith.edu/~orourke/MathOverflow/RainColumn.jpg" alt="RainColumn" /> <br /> Perhaps the computation is NP-hard if $M$ is presented as a PL-manifold? TINs have special properties that might render the computation polynomial. Let us assume we have $\overline{M} = H_R(M)$ computed or given. A raindrop falling on $p \in \overline{M}$ might follow a unique _trickle path_ (that is the technical term: e.g., see <a href="http://eurocg11.inf.ethz.ch/abstracts/60.pdf">"Implicit Flow Routing on Triangulated Terrains" by deBerg et al.</a>) to the ocean, or the drop may randomly 'fracture' to follow distinct paths to the ocean. Define the _rain ridge_ (my terminology) $R(\overline{M})$ to be the complement of the points of $\overline{M}$ that have a unique trickle path. So points on the rain ridge are akin to points on a [cut locus][1], in that they have two or more distinct paths to $\partial \overline{M}$. They are, in a sense, _continental-divide_ points, a topic explored in <a href="http://mathoverflow.net/questions/48716/">this inadequately answered MO question</a> (inadequately answered by me). <b>Q2.</b> What can be said about the structure of the rain ridge $R(\overline{M})$? Unlike the cut locus, it is not always a tree. All the points in a filled basin are in the rain ridge, for when a raindrop lands in a filled basin, it is natural to assume it "spreads out" and spills in equal portions over every boundary point of the basin. But surely there are substantive properties to investigate. Surely the rain ridge $R(\overline{M})$ cannot be an arbitrary subset of $\overline{M}$? I finally come to my main question, which I fear has a negative answer: <b>Q3.</b> Can an extended metric be assigned to $\overline{M}$ so that its geodesics are its trickle paths? An <a href="http://en.wikipedia.org/wiki/Metric_%28mathematics%29#Extended_metrics">extended metric</a> is one that permits $d(x,y) = \infty$ (e.g., for points not on the same trickle path). What I am hoping for here is a way to view the rain ridge as a cut locus of $\partial \overline{M}$, and then apply a century of knowledge on the cut locus to the rain ridge. Partly baked ideas, subquestion observations, and random literature pointers all welcomed! My sense is that the considerable applied-math literature on watersheds has not approached these questions in their full mathematical generality, leaving room for delightful theorems. [1]: http://en.wikipedia.org/wiki/Cut_locus