Stack-based memory corruption vulnerabilities have long been exploited by attackers to execute arbitrary code or perform unauthorized memory operations. Various defense mechanisms have been introduced to mitigate stack memory errors, but they typically focus on specific attack types (such as control-flow hijacking or non-control data attacks), incur substantial performance overhead, or suffer from compatibility limitations.In this paper, we present CleanStack, an efficient, highly compatible, and comprehensive stack protection mechanism. CleanStack isolates stack objects influenced by external input from other safe stack objects, thereby preventing attackers from modifying return addresses via controlled stack objects. Additionally, by randomizing the placement of tainted stack objects within the Unclean Stack, CleanStack mitigates non-control data attacks by preventing attackers from predicting the stack layout.A key component of CleanStack is the identification of tainted stack objects. We analyze both static program analysis and heuristic methods for this purpose. To maximize compatibility, we adopt a heuristic approach and implement CleanStack within the LLVM compiler framework, applying it to SPEC CPU2017 benchmarks and a real-world application.Our security evaluation demonstrates that CleanStack significantly reduces the exploitability of stack-based memory errors by providing a dual-stack system with isolation and randomization. Performance evaluation results indicate that CleanStack incurs an execution overhead of only 1.73% on the SPEC CPU2017 benchmark while introducing a minimal memory overhead of just 0.04%. Compared to existing stack protection techniques, CleanStack provides broader protection coverage while maintaining low runtime overhead and good compatibility with existing compiler infrastructure, making it a practical and effective stack security solution.
Lei et al. (Mon,) studied this question.