Research article Special Issues

Cross-platform binary code similarity detection based on NMT and graph embedding

  • Received: 12 March 2021 Accepted: 10 May 2021 Published: 25 May 2021
  • Cross-platform binary code similarity detection is determining whether a pair of binary functions coming from different platforms are similar, and plays an important role in many areas. Traditional methods focus on using platform-independent characteristic strands intersecting or control flow graph (CFG) matching to compute the similarity and have shortages in terms of efficiency and scalability. The existing deep-learning-based methods improve the efficiency but have a low accuracy and still using manually constructed features. Aiming at these problems, a cross-platform binary code similarity detection method based on neural machine translation (NMT) and graph embedding is proposed in this manuscript. We train an NMT model and a graph embedding model to automatically extract two parts of semantics of the binary code and represent it as a high-dimension vector, named an embedding. Then the similarity of two binary functions can be measured by the distance between their corresponding embeddings. We implement a prototype named SimInspector. Our comparative experiment result shows that SimInspector outperforms the state-of-the-art approach, Gemini, by about 6$ \% $ with respect to similarity detection accuracy, and maintains a good efficiency.

    Citation: Xiaodong Zhu, Liehui Jiang, Zeng Chen. Cross-platform binary code similarity detection based on NMT and graph embedding[J]. Mathematical Biosciences and Engineering, 2021, 18(4): 4528-4551. doi: 10.3934/mbe.2021230

    Related Papers:

  • Cross-platform binary code similarity detection is determining whether a pair of binary functions coming from different platforms are similar, and plays an important role in many areas. Traditional methods focus on using platform-independent characteristic strands intersecting or control flow graph (CFG) matching to compute the similarity and have shortages in terms of efficiency and scalability. The existing deep-learning-based methods improve the efficiency but have a low accuracy and still using manually constructed features. Aiming at these problems, a cross-platform binary code similarity detection method based on neural machine translation (NMT) and graph embedding is proposed in this manuscript. We train an NMT model and a graph embedding model to automatically extract two parts of semantics of the binary code and represent it as a high-dimension vector, named an embedding. Then the similarity of two binary functions can be measured by the distance between their corresponding embeddings. We implement a prototype named SimInspector. Our comparative experiment result shows that SimInspector outperforms the state-of-the-art approach, Gemini, by about 6$ \% $ with respect to similarity detection accuracy, and maintains a good efficiency.



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