SpChar: Characterizing the Sparse Puzzle via Decision Trees

Sparse matrix computation is crucial in various modern applications, including large-scale graph analytics, deep learning, and recommendation systems. The performance of these algorithms varies greatly depending on the structure of the input matrix, making it difficult to gain a comprehensive understanding of sparse computation and its relationship to inputs, algorithms, and target machine architecture. Despite extensive research on certain sparse algorithms, such as SpMV, the overall family of sparse algorithms has yet to be investigated as a whole. In this paper, we introduce SpChar, a workload characterization methodology for general sparse computation. SpChar employs tree-based models to identify the most relevant hardware and input characteristics, starting from hardware and input-related metrics gathered from Performance Monitoring Counters and matrices. Our analysis enables the creation of a characterization loop that facilitates the optimization of sparse computation by mapping the impact of architectural features to inputs and algorithmic choices. We apply SpChar to more than 600 matrices from the SuiteSparse Matrix collection and three state-of-the-art Arm CPUs to determine the critical hardware and software characteristics that affect sparse computation. In our analysis, we determine that the biggest limiting factors for high-performance sparse computation are (1) the latency of the memory system, (2) the pipeline flush overhead resulting from branch misprediction, and (3) the poor reuse of cached elements. However, the degree to which those impact the performance of a CPU greatly depends on the algorithm and the input data.