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Tailors: Accelerating Sparse Tensor Algebra by Overbooking Buffer Capacity

Hardware Architecture 2024-06-27 v2

Abstract

Sparse tensor algebra is a challenging class of workloads to accelerate due to low arithmetic intensity and varying sparsity patterns. Prior sparse tensor algebra accelerators have explored tiling sparse data to increase exploitable data reuse and improve throughput, but typically allocate tile size in a given buffer for the worst-case data occupancy. This severely limits the utilization of available memory resources and reduces data reuse. Other accelerators employ complex tiling during preprocessing or at runtime to determine the exact tile size based on its occupancy. This paper proposes a speculative tensor tiling approach, called overbooking, to improve buffer utilization by taking advantage of the distribution of nonzero elements in sparse tensors to construct larger tiles with greater data reuse. To ensure correctness, we propose a low-overhead hardware mechanism, Tailors, that can tolerate data overflow by design while ensuring reasonable data reuse. We demonstrate that Tailors can be easily integrated into the memory hierarchy of an existing sparse tensor algebra accelerator. To ensure high buffer utilization with minimal tiling overhead, we introduce a statistical approach, Swiftiles, to pick a tile size so that tiles usually fit within the buffer's capacity, but can potentially overflow, i.e., it overbooks the buffers. Across a suite of 22 sparse tensor algebra workloads, we show that our proposed overbooking strategy introduces an average speedup of 52.7×52.7\times and 2.3×2.3\times and an average energy reduction of 22.5×22.5\times and 2.5×2.5\times over ExTensor without and with optimized tiling, respectively.

Keywords

Cite

@article{arxiv.2310.00192,
  title  = {Tailors: Accelerating Sparse Tensor Algebra by Overbooking Buffer Capacity},
  author = {Zi Yu Xue and Yannan Nellie Wu and Joel S. Emer and Vivienne Sze},
  journal= {arXiv preprint arXiv:2310.00192},
  year   = {2024}
}

Comments

17 pages, 13 figures, in MICRO 2023

R2 v1 2026-06-28T12:36:49.508Z