Contraction Hierarchies (CH) (Geisberger et al., 2008) is one of the most widely used algorithms for shortest-path queries on road networks. Compared to Dijkstra's algorithm, CH enables orders of magnitude faster query performance through a preprocessing phase, which iteratively categorizes vertices into hierarchies and adds shortcuts. However, constructing a CH is an expensive task. Existing solutions, including parallel ones, may suffer from long construction time. Especially in our experiments, we observe that existing parallel solutions demonstrate unsatisfactory scalability and have close performance to sequential algorithms. In this paper, we present \textsf{SPoCH} (\textbf{S}calable \textbf{P}arallelization \textbf{o}f \textbf{C}ontraction \textbf{H}ierarchies), an efficient and scalable CH construction algorithm in parallel. To address the challenges in previous work, our improvements focus on both redesigning the algorithm and leveraging parallel data structures. %to maintain the original and shortcut edges dynamically. We implement our algorithm and compare it with the state-of-the-art sequential and parallel implementations on 13 graphs, including road networks, synthetic graphs, and $k$-NN graphs. Our experiments show that \textsf{SPoCH} achieves $17$--$131\times$ speedups in CH construction over the best baseline, while maintaining competitive query performance and CH graph size.

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