安全虚拟体系结构:商用操作系统的安全执行环境

J. Criswell, Andrew Lenharth, Dinakar Dhurjati, Vikram S. Adve
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引用次数: 159

摘要

本文描述了一种为整个操作系统(如Linux)及其所有应用程序提供安全执行环境的高效且健壮的方法。这种方法,我们称之为安全虚拟体系结构(SVA),它定义了一个虚拟的、低级的、类型化的指令集,适用于执行系统上的所有代码,包括内核和应用程序代码。SVA代码被转换为由虚拟机透明地、离线或在线执行。SVA旨在加强细粒度(对象级)内存安全性、控制流完整性、对象子集的类型安全性以及可靠的分析。实现SVA的虚拟机通过使用一种新颖的方法来实现这些目标,这种方法利用内核中现有内存池的属性,并保留内核对内存的显式控制,包括自定义分配器和显式释放。此外,安全属性可以作为SVA类型系统的扩展进行紧凑编码,从而允许(复杂的)安全检查编译器位于可信计算库之外。SVA还定义了一组操作系统接口操作,这些操作抽象了所有特权硬件指令,允许虚拟机监视所有特权操作并控制给定硬件平台上的物理资源。我们已经将Linux内核移植到SVA,将其视为一种新的体系结构,并且只对内核和设备驱动程序中与机器无关的部分进行了最小的代码更改(少于300行代码)。SVA能够阻止先前报告的针对Linux 2.4.22内核的5个内存安全漏洞中的4个,并且可以通过编译额外的内核库来防止第5个漏洞。
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Secure virtual architecture: a safe execution environment for commodity operating systems
This paper describes an efficient and robust approach to provide a safe execution environment for an entire operating system, such as Linux, and all its applications. The approach, which we call Secure Virtual Architecture (SVA), defines a virtual, low-level, typed instruction set suitable for executing all code on a system, including kernel and application code. SVA code is translated for execution by a virtual machine transparently, offline or online. SVA aims to enforce fine-grained (object level) memory safety, control-flow integrity, type safety for a subset of objects, and sound analysis. A virtual machine implementing SVA achieves these goals by using a novel approach that exploits properties of existing memory pools in the kernel and by preserving the kernel's explicit control over memory, including custom allocators and explicit deallocation. Furthermore, the safety properties can be encoded compactly as extensions to the SVA type system, allowing the (complex) safety checking compiler to be outside the trusted computing base. SVA also defines a set of OS interface operations that abstract all privileged hardware instructions, allowing the virtual machine to monitor all privileged operations and control the physical resources on a given hardware platform. We have ported the Linux kernel to SVA, treating it as a new architecture, and made only minimal code changes (less than 300 lines of code) to the machine-independent parts of the kernel and device drivers. SVA is able to prevent 4 out of 5 memory safety exploits previously reported for the Linux 2.4.22 kernel for which exploit code is available, and would prevent the fifth one simply by compiling an additional kernel library.
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