1,680 research outputs found
Wild Patterns: Ten Years After the Rise of Adversarial Machine Learning
Learning-based pattern classifiers, including deep networks, have shown
impressive performance in several application domains, ranging from computer
vision to cybersecurity. However, it has also been shown that adversarial input
perturbations carefully crafted either at training or at test time can easily
subvert their predictions. The vulnerability of machine learning to such wild
patterns (also referred to as adversarial examples), along with the design of
suitable countermeasures, have been investigated in the research field of
adversarial machine learning. In this work, we provide a thorough overview of
the evolution of this research area over the last ten years and beyond,
starting from pioneering, earlier work on the security of non-deep learning
algorithms up to more recent work aimed to understand the security properties
of deep learning algorithms, in the context of computer vision and
cybersecurity tasks. We report interesting connections between these
apparently-different lines of work, highlighting common misconceptions related
to the security evaluation of machine-learning algorithms. We review the main
threat models and attacks defined to this end, and discuss the main limitations
of current work, along with the corresponding future challenges towards the
design of more secure learning algorithms.Comment: Accepted for publication on Pattern Recognition, 201
Adversarial Detection of Flash Malware: Limitations and Open Issues
During the past four years, Flash malware has become one of the most
insidious threats to detect, with almost 600 critical vulnerabilities targeting
Adobe Flash disclosed in the wild. Research has shown that machine learning can
be successfully used to detect Flash malware by leveraging static analysis to
extract information from the structure of the file or its bytecode. However,
the robustness of Flash malware detectors against well-crafted evasion attempts
- also known as adversarial examples - has never been investigated. In this
paper, we propose a security evaluation of a novel, representative Flash
detector that embeds a combination of the prominent, static features employed
by state-of-the-art tools. In particular, we discuss how to craft adversarial
Flash malware examples, showing that it suffices to manipulate the
corresponding source malware samples slightly to evade detection. We then
empirically demonstrate that popular defense techniques proposed to mitigate
evasion attempts, including re-training on adversarial examples, may not always
be sufficient to ensure robustness. We argue that this occurs when the feature
vectors extracted from adversarial examples become indistinguishable from those
of benign data, meaning that the given feature representation is intrinsically
vulnerable. In this respect, we are the first to formally define and
quantitatively characterize this vulnerability, highlighting when an attack can
be countered by solely improving the security of the learning algorithm, or
when it requires also considering additional features. We conclude the paper by
suggesting alternative research directions to improve the security of
learning-based Flash malware detectors
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