The greedy spanner is the highest quality geometric spanner (in e.g. edge count and weight, both in theory and practice) known to be computable in polynomial time. Unfortunately, all known algorithms for computing it take Ω(n2) time, limiting its applicability on large data sets. We observe that for many point sets, the greedy spanner has many ‘short ’ edges that can be determined locally and usually quickly, and few or no ‘long ’ edges that can usually be determined quickly using local information and the well-separated pair decomposition. We give experimental results showing large to massive performance increases over the state-of-the-art on nearly all tests and real-life data sets. On the theoretical side we prove a near-linear expected ...