Building on two recent models of [Almalki and Michail, 2022] and [Gupta et al., 2023], we explore the constructive power of a set of geometric growth processes. The studied processes, by applying a sequence of centralized, parallel, and linear-strength growth operations, can construct shapes from smaller shapes or from a singleton exponentially fast. A technical challenge in growing shapes that fast is the need to avoid collisions caused, for example, when the shape breaks, stretches, or self-intersects. We distinguish two types of growth operations -- one that avoids collisions by preserving cycles and one that achieves the same by breaking them -- and two types of graph models. We study the following types of shape reachability questions in these models. Given a class of initial shapes $\mathcal{I}$ and a class of final shapes $\mathcal{F}$, our objective is to determine whether any (some) shape $S \in \mathcal{F}$ can be reached from any shape $S_0 \in \mathcal{I}$ in a number of time steps which is (poly)logarithmic in the size of $S$. For the reachable classes, we additionally present the respective growth processes. In cycle-preserving growth, we study these problems in basic classes of shapes such as paths, spirals, and trees and reveal the importance of the number of turning points as a parameter. We give both positive and negative results. For cycle-breaking growth, we obtain a strong positive result -- a general growth process that can grow any connected shape from a singleton fast.