安全且经过认证的Linux KVM虚拟化环境

Shih-wei Li, Xupeng Li, Ronghui Gu, Jason Nieh, J. Hui
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引用次数: 37

摘要

商品管理程序被广泛部署以支持多处理器硬件上的虚拟机。它们日益增长的复杂性构成了安全风险。为了对如此大的代码库进行正式验证,我们引入了微验证,这是一种新的方法,它将商品管理程序分解为一个小核心和一组不受信任的服务,这样我们就可以通过单独验证核心来证明整个管理程序的安全属性。为了验证多处理器管理程序核心,我们引入了安全保护层,在不隐藏信息泄漏的情况下将证明模块化,从而证明实现的每一层都对其规范进行了细化,并且核心实现的所有层都对顶层规范进行了细化。为了验证需要动态更改信息流的商品管理程序特性,我们引入了数据oracle来掩盖有意的信息流。然后,我们可以证明顶层规范的不干扰性,并保证最终的安全属性适用于整个管理程序实现。使用微验证,我们对Linux KVM管理程序进行了改进,仅对其代码库进行了适度的修改。通过使用Coq,我们证明了虚拟机管理程序保护了VM数据的机密性和完整性,同时保留了KVM的功能和性能。我们的工作是商用多处理器管理程序的第一个机器检查安全性证明。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Secure and Formally Verified Linux KVM Hypervisor
Commodity hypervisors are widely deployed to support virtual machines (VMs) on multiprocessor hardware. Their growing complexity poses a security risk. To enable formal verification over such a large codebase, we introduce microverification, a new approach that decomposes a commodity hypervisor into a small core and a set of untrusted services so that we can prove security properties of the entire hypervisor by verifying the core alone. To verify the multiprocessor hypervisor core, we introduce security-preserving layers to modularize the proof without hiding information leakage so we can prove each layer of the implementation refines its specification, and the top layer specification is refined by all layers of the core implementation. To verify commodity hypervisor features that require dynamically changing information flow, we introduce data oracles to mask intentional information flow. We can then prove noninterference at the top layer specification and guarantee the resulting security properties hold for the entire hypervisor implementation. Using microverification, we retrofitted the Linux KVM hypervisor with only modest modifications to its codebase. Using Coq, we proved that the hypervisor protects the confidentiality and integrity of VM data, while retaining KVM’s functionality and performance. Our work is the first machine-checked security proof for a commodity multiprocessor hypervisor.
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