压缩结构化张量代数

arXiv - CS - Programming Languages Pub Date : 2024-07-18 DOI:arxiv-2407.13726

Mahdi Ghorbani, Emilien Bauer, Tobias Grosser, Amir Shaikhha

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引用次数: 0

摘要

张量代数是机器学习和科学计算等数据密集型工作负载的重要组成部分。随着数据复杂度的增加，科学家们经常会在高度专业化的张量代数和高效的结构感知算法之间左右为难。在本文中，我们介绍了 DASTAC，这是一个通过整合自动数据布局压缩、多面体分析和仿射代码生成等技术，将捕捉到的张量高层结构传播到底层代码生成的框架。我们的方法通过自动检测最佳数据布局来减少内存足迹，从多面体优化中获益匪浅，充分利用进一步优化，并通过 MLIR 实现并行化。通过大量实验，我们发现与最先进的稀疏张量编译器 TACO 和最先进的结构化张量代数编译器 StructTensor 相比，DASTAC 的速度提高了 1 到 2 个数量级，内存足迹也显著降低。

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Compressing Structured Tensor Algebra

Tensor algebra is a crucial component for data-intensive workloads such as machine learning and scientific computing. As the complexity of data grows, scientists often encounter a dilemma between the highly specialized dense tensor algebra and efficient structure-aware algorithms provided by sparse tensor algebra. In this paper, we introduce DASTAC, a framework to propagate the tensors's captured high-level structure down to low-level code generation by incorporating techniques such as automatic data layout compression, polyhedral analysis, and affine code generation. Our methodology reduces memory footprint by automatically detecting the best data layout, heavily benefits from polyhedral optimizations, leverages further optimizations, and enables parallelization through MLIR. Through extensive experimentation, we show that DASTAC achieves 1 to 2 orders of magnitude speedup over TACO, a state-of-the-art sparse tensor compiler, and StructTensor, a state-of-the-art structured tensor algebra compiler, with a significantly lower memory footprint.

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arXiv - CS - Programming Languages

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