Language-based information flow methods offer a principled way to enforce strong security properties, but enforcing noninterference is too inflexible for realistic applications. Security-typed languages have therefore introduced declassification mechanisms for relaxing confidentiality policies, and endorsement mechanisms for relaxing integrity policies. However, a continuing challenge has been to define what security is guaranteed when such mechanisms are used. This paper presents a new semantic framework for expressing security policies for declassification and endorsement in a language-based setting. The key insight is that security can be described in terms of the power that declassification and endorsement give the attacker. The new framework specifies how attacker-controlled code affects program execution and what the attacker is able to learn from observable effects of this code. This approach yields novel security conditions for checked endorsements and robust integrity. The framework is flexible enough to recover and to improve on the previously introduced notions of robustness and qualified robustness. Further, the new security conditions can be soundly enforced by a security type system. The applicability and enforcement of the new policies is illustrated through various examples, including data sanitization and authentication.
CITATION STYLE
Askarov, A., & Myers, A. (2010). A Semantic Framework for Declassification and Endorsement (pp. 64–84). https://doi.org/10.1007/978-3-642-11957-6_5
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