Haskell中的规则、形状多态、并行数组

Proceedings of the 18th ACM SIGPLAN international conference on Functional programming Pub Date : 2010-09-27 DOI:10.1145/1863543.1863582

G. Keller, M. Chakravarty, Roman Leshchinskiy, S. Jones, B. Lippmeier

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引用次数: 166

摘要

我们提出了一种在Haskell中处理常规多维数组的新方法。我们的方法的主要亮点是它(1)是纯功能性的，(2)通过形状多态性支持重用，(3)避免不必要的中间结构，而不是依赖于随后的循环融合，以及(4)支持透明并行化。我们将展示如何使用类型类和类型族将两种形式的形状多态性嵌入Haskell的类型系统。特别地，我们讨论了正则数组转换到更高秩数组的推广，并引入了数组切片的类型安全规范。我们讨论了三种标准数组算法的运行时性能。我们实现了与手写C代码相当的绝对性能。同时，我们的实现可以扩展到8个处理器内核。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Regular, shape-polymorphic, parallel arrays in Haskell

We present a novel approach to regular, multi-dimensional arrays in Haskell. The main highlights of our approach are that it (1) is purely functional, (2) supports reuse through shape polymorphism, (3) avoids unnecessary intermediate structures rather than relying on subsequent loop fusion, and (4) supports transparent parallelisation. We show how to embed two forms of shape polymorphism into Haskell's type system using type classes and type families. In particular, we discuss the generalisation of regular array transformations to arrays of higher rank, and introduce a type-safe specification of array slices. We discuss the runtime performance of our approach for three standard array algorithms. We achieve absolute performance comparable to handwritten C code. At the same time, our implementation scales well up to 8 processor cores.

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Proceedings of the 18th ACM SIGPLAN international conference on Functional programming

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