The shape of homogeneous, generic, smooth convex bodies as described by the Euclidean
distance with nondegenerate critical points, measured from the center of mass represents
a rather restricted class of Morse-Smale functions on . Here we show that even exhibits
the complexity known for general Morse-Smale functions on by exhausting all combinatorial
possibilities: every 2-colored quadrangulation of the sphere is isomorphic to a suitably
represented Morse-Smale complex associated with a function in (and vice versa). We
prove our claim by an inductive algorithm, starting from the path graph and generating
convex bodies corresponding to quadrangulations with increasing number of vertices
by performing each combinatorially possible vertex splitting by a convexity-preserving
local manipulation of the surface. Since convex bodies carrying Morse-Smale complexes
isomorphic to exist, this algorithm not only proves our claim but also generalizes
the known classification scheme in Varkonyi and Domokos (J Nonlinear Sci 16:255-281,
2006). Our expansion algorithm is essentially the dual procedure to the algorithm
presented by Edelsbrunner et al. (Discrete Comput Geom 30:87-10, 2003), producing
a hierarchy of increasingly coarse Morse-Smale complexes. We point out applications
to pebble shapes.