Discrete Spacetime Effects:** If spacetime is emergent from a discrete graph, then at the Planck scale, there may be "seams" or "glitches"—anisotropic effects or violations of perfect Lorentz invariance—that could be detectable in high-energy cosmic ray data or gravitational wave astronomy. * **Evolving Physical Constants:** The balance of the Cosmic Trilemma may not be static over cosmic history. This implies that fundamental constants, which are expressions of this balance, might not be perfectly constant. Searches for tiny, systematic variations in constants like the fine-structure constant over cosmological time could provide evidence for a dynamic `L_A`. * **Computational Signatures in the CMB:** The Cosmic Microwave Background might contain statistical signatures of the early universe's generative process, reflecting the specific `L_A` and operators that governed that era. This would be akin to finding artifacts of the "compiler" in the universe's "boot-up screen." * **Generative Particle Physics:** Instead of building ever-larger colliders, a complementary approach would be to build "computational colliders"—massive simulations that evolve simple graphs according to candidate `L_A` functions. Success would be defined by the spontaneous emergence of stable, interacting patterns with the same mass ratios and charges as the particles in the Standard Model.