A vulnerability detection framework with enhanced graph feature learning

IF 3.7 2区计算机科学 Q1 COMPUTER SCIENCE, SOFTWARE ENGINEERING Journal of Systems and Software Pub Date : 2024-06-01 DOI:10.1016/j.jss.2024.112118

Jianxin Cheng , Yizhou Chen , Yongzhi Cao , Hanpin Wang

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Abstract

Vulnerability detection in smart contracts is critical to secure blockchain systems. Existing methods represent the bytecode as a graph structure and leverage graph neural networks to learn graph features for vulnerability detection. However, these methods are limited to handling the long-range dependencies between nodes. This means that they might focus on learning local node feature while ignoring global node information. In this paper, we propose a novel vulnerability detection framework with Enhanced Graph Feature Learning (EGFL), which aims to extract the global node information and utilize it to improve vulnerability detection in smart contracts. Specifically, we first represent the bytecode as a Control Flow Graph (CFG). To extract global node information, EGFL constructs a linear node feature matrix from CFG, and uses the feature-aware and relationship-aware modules to handle long-range dependencies between nodes. Meanwhile, a graph neural network is adopted to extract the local node feature from CFG. Subsequently, we fuse the global node information and local node feature to generate an enhanced graph feature for capturing more vulnerability features. We evaluate EGFL on the benchmark dataset with six types of smart contract vulnerabilities. Results show that EGFL outperforms fourteen state-of-the-art vulnerability detection methods by 10.83%–60.28% in F1 score.

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利用增强型图形特征学习的漏洞检测框架

智能合约中的漏洞检测对于确保区块链系统的安全至关重要。现有方法将字节码表示为图结构，并利用图神经网络来学习图特征，从而进行漏洞检测。然而，这些方法仅限于处理节点之间的长距离依赖关系。这意味着它们可能只关注局部节点特征的学习，而忽略了全局节点信息。在本文中，我们利用增强型图特征学习（EGFL）提出了一种新颖的漏洞检测框架，旨在提取全局节点信息并利用它来改进智能合约中的漏洞检测。具体来说，我们首先将字节码表示为控制流图（CFG）。为了提取全局节点信息，EGFL 从 CFG 中构建了一个线性节点特征矩阵，并使用特征感知模块和关系感知模块来处理节点之间的远距离依赖关系。同时，采用图神经网络从 CFG 中提取局部节点特征。随后，我们融合全局节点信息和局部节点特征，生成增强图特征，以捕捉更多的脆弱性特征。我们在包含六种智能合约漏洞的基准数据集上对 EGFL 进行了评估。结果表明，EGFL 的 F1 分数比 14 种最先进的漏洞检测方法高出 10.83%-60.28% 。

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来源期刊

Journal of Systems and Software 工程技术-计算机：理论方法

CiteScore

8.60

自引率

5.70%

发文量

193

审稿时长

16 weeks

期刊介绍： The Journal of Systems and Software publishes papers covering all aspects of software engineering and related hardware-software-systems issues. All articles should include a validation of the idea presented, e.g. through case studies, experiments, or systematic comparisons with other approaches already in practice. Topics of interest include, but are not limited to: • Methods and tools for, and empirical studies on, software requirements, design, architecture, verification and validation, maintenance and evolution • Agile, model-driven, service-oriented, open source and global software development • Approaches for mobile, multiprocessing, real-time, distributed, cloud-based, dependable and virtualized systems • Human factors and management concerns of software development • Data management and big data issues of software systems • Metrics and evaluation, data mining of software development resources • Business and economic aspects of software development processes The journal welcomes state-of-the-art surveys and reports of practical experience for all of these topics.

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