Fissile type analysis: modular checking of almost everywhere invariants

Devin Coughlin, B. E. Chang
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引用次数: 7

Abstract

We present a generic analysis approach to the imperative relationship update problem, in which destructive updates temporarily violate a global invariant of interest. Such invariants can be conveniently and concisely specified with dependent refinement types, which are efficient to check flow-insensitively. Unfortunately, while traditional flow-insensitive type checking is fast, it is inapplicable when the desired invariants can be temporarily broken. To overcome this limitation, past works have directly ratcheted up the complexity of the type analysis and associated type invariants, leading to inefficient analysis and verbose specifications. In contrast, we propose a generic lifting of modular refinement type analyses with a symbolic analysis to efficiently and effectively check concise invariants that hold almost everywhere. The result is an efficient, highly modular flow-insensitive type analysis to optimistically check the preservation of global relationship invariants that can fall back to a precise, disjunctive symbolic analysis when the optimistic assumption is violated. This technique permits programmers to temporarily break and then re-establish relationship invariants--a flexibility that is crucial for checking relationships in real-world, imperative languages. A significant challenge is selectively violating the global type consistency invariant over heap locations, which we achieve via almost type-consistent heaps. To evaluate our approach, we have encoded the problem of verifying the safety of reflective method calls in dynamic languages as a refinement type checking problem. Our analysis is capable of validating reflective call safety at interactive speeds on commonly-used Objective-C libraries and applications.
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裂变型分析:几乎所有不变量的模检验
我们提出了一种通用的分析方法来解决命令式关系更新问题,其中破坏性更新暂时违反了感兴趣的全局不变量。这些不变量可以用依赖的细化类型来方便、简洁地指定,从而有效地进行流不敏感的检查。不幸的是,虽然传统的流不敏感类型检查速度很快,但当期望的不变量可能暂时被破坏时,它就不适用了。为了克服这一限制,过去的工作直接增加了类型分析和相关类型不变量的复杂性,导致了低效的分析和冗长的规范。相比之下,我们提出了一个通用的提升模块细化类型分析与符号分析,以有效和有效地检查简洁的不变量,几乎无处不在。结果是一种高效的、高度模块化的流不敏感型分析,用于乐观地检查全局关系不变量的保存,当乐观假设被违反时,这些不变量可以回落到精确的、析取的符号分析。这种技术允许程序员暂时中断关系不变量,然后重新建立关系不变量——这种灵活性对于在现实世界的命令式语言中检查关系至关重要。一个重要的挑战是有选择地违反堆位置上的全局类型一致性不变量,这是我们通过几乎类型一致的堆实现的。为了评估我们的方法,我们将验证动态语言中反射方法调用的安全性的问题编码为细化类型检查问题。我们的分析能够在常用的Objective-C库和应用程序上以交互速度验证反射调用安全性。
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Session details: Verified systems Session details: Semantic models 2 Session details: Program analysis 3 Session details: Program analysis 1 Session details: Type system design
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