方案B: Java的缓冲内存模型

Delphine Demange, Vincent Laporte, Lei Zhao, S. Jagannathan, David Pichardie, J. Vitek
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引用次数: 41

摘要

验证方面的最新进展已经使设想真实世界语言的可信实现成为可能。具有类型安全和完全指定语义的Java似乎是一个理想的候选者;然而,生产虚拟机中使用的翻译步骤的复杂性使得验证编译器技术成为一个具有挑战性的目标。Java的关键创新之一,它的内存模型,给这种努力带来了巨大的障碍。Java内存模型是一项雄心勃勃的尝试,旨在以可移植的、与硬件无关的方式指定多线程程序的行为。虽然专家对模型应该享有的属性有直观的把握,但是规范是复杂的,并且不适合在验证编译器基础结构中集成。此外,该规范以一种公理的风格给出,与传统上用于证明或排除行为的基于重新排序的直观推理相去甚远,并且不适合期望在编译器中使用的那种操作推理。本文退一步介绍了Java的缓冲内存模型(BMM)。我们在设计空间中选择了一个实用的点,牺牲了通用性,以支持一个模型,该模型在其允许的重新排序方面具有完全的特征,符合形式推理,并且可以有效地应用于特定的硬件系列,即x86多处理器。尽管BMM限制了编译器允许执行的重排序,但它是实现从字节码到机器指令的验证路径的关键启用设备。尽管有其限制,但我们证明了它与Java内存模型向后兼容,并且不会削弱TSO体系结构上的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Plan B: a buffered memory model for Java
Recent advances in verification have made it possible to envision trusted implementations of real-world languages. Java with its type-safety and fully specified semantics would appear to be an ideal candidate; yet, the complexity of the translation steps used in production virtual machines have made it a challenging target for verifying compiler technology. One of Java's key innovations, its memory model, poses significant obstacles to such an endeavor. The Java Memory Model is an ambitious attempt at specifying the behavior of multithreaded programs in a portable, hardware agnostic, way. While experts have an intuitive grasp of the properties that the model should enjoy, the specification is complex and not well-suited for integration within a verifying compiler infrastructure. Moreover, the specification is given in an axiomatic style that is distant from the intuitive reordering-based reasonings traditionally used to justify or rule out behaviors, and ill suited to the kind of operational reasoning one would expect to employ in a compiler. This paper takes a step back, and introduces a Buffered Memory Model (BMM) for Java. We choose a pragmatic point in the design space sacrificing generality in favor of a model that is fully characterized in terms of the reorderings it allows, amenable to formal reasoning, and which can be efficiently applied to a specific hardware family, namely x86 multiprocessors. Although the BMM restricts the reorderings compilers are allowed to perform, it serves as the key enabling device to achieving a verification pathway from bytecode to machine instructions. Despite its restrictions, we show that it is backwards compatible with the Java Memory Model and that it does not cripple performance on TSO architectures.
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