Valent-Blocks: Scalable High-Performance Compilation of WebAssembly Bytecode For Embedded Systems

2020 International Conference on Computing, Electronics & Communications Engineering (iCCECE) Pub Date : 2020-08-17 DOI:10.1109/iCCECE49321.2020.9231154

Fabian Scheidl

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引用次数: 2

Abstract

In the field of emerging software architectures, there has been a dramatic push towards flexible and sand-boxed software modules that allow systems to safely execute untrusted code in a guaranteed side-effect free manner. Latest developments have further given rise to portable and statically validatable representations of software in a bytecode format like WebAssembly. In order to ease the segue into the domain of embedded systems, this paper explores the feasibility of a novel and easily retargetable streaming quasi-singlepass on-target-compiler topology with concurrent bytecode validation. For this, a generalized compile-time virtual stack is employed which is logically partitioned into separately emittable blocks (named valent-blocks). This forms the foundation of a corresponding runtime for resource constrained systems that demonstrate the need for predictable, resource-efficient and fast sandboxed execution of hot-loaded software. This paper further benchmarks the resultant performance against current popular competing standalone WebAssembly runtimes.

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有价块:嵌入式系统WebAssembly字节码的可伸缩高性能编译

在新兴的软件体系结构领域，出现了一种向灵活和沙箱软件模块的巨大推动，这种软件模块允许系统以保证无副作用的方式安全地执行不受信任的代码。最近的发展进一步产生了可移植和静态验证的软件表示，采用字节码格式，如WebAssembly。为了方便深入嵌入式系统领域，本文探讨了一种具有并发字节码验证的易于重定向的流准单通目标编译器拓扑结构的可行性。为此，使用了一个通用的编译时虚拟堆栈，它在逻辑上被划分为单独的可发射块(称为价块)。这为资源受限的系统形成了相应运行时的基础，这些系统证明了对热加载软件的可预测、资源高效和快速沙盒执行的需求。本文将进一步对当前流行的独立WebAssembly运行时的性能进行基准测试。

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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2020 International Conference on Computing, Electronics & Communications Engineering (iCCECE)

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