Litcius/Paper detail

Neural reverse engineering of stripped binaries using augmented control flow graphs

Yaniv David, Uri Alon, Eran Yahav

2020Proceedings of the ACM on Programming Languages75 citationsDOIOpen Access PDF

Abstract

We address the problem of reverse engineering of stripped executables, which contain no debug information. This is a challenging problem because of the low amount of syntactic information available in stripped executables, and the diverse assembly code patterns arising from compiler optimizations. We present a novel approach for predicting procedure names in stripped executables. Our approach combines static analysis with neural models. The main idea is to use static analysis to obtain augmented representations of call sites; encode the structure of these call sites using the control-flow graph (CFG) and finally, generate a target name while attending to these call sites. We use our representation to drive graph-based, LSTM-based and Transformer-based architectures. Our evaluation shows that our models produce predictions that are difficult and time consuming for humans, while improving on existing methods by 28% and by 100% over state-of-the-art neural textual models that do not use any static analysis. Code and data for this evaluation are available at https://github.com/tech-srl/Nero.

Topics & Concepts

ExecutableComputer scienceReverse engineeringCompilerDebuggingControl flow graphControl flowProgramming languageENCODESource codeGraphData-flow analysisTransformerTheoretical computer scienceRepresentation (politics)Data flow diagramDatabasePolitical scienceLawChemistryVoltageBiochemistryPhysicsPoliticsQuantum mechanicsGeneSoftware Engineering ResearchSoftware Testing and Debugging TechniquesAdvanced Malware Detection Techniques