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Qu-ANTI-zation: Exploiting Quantization Artifacts for Achieving Adversarial Outcomes

Machine Learning 2021-11-12 v2 Cryptography and Security

Abstract

Quantization is a popular technique that transformstransforms the parameter representation of a neural network from floating-point numbers into lower-precision ones (e.g.e.g., 8-bit integers). It reduces the memory footprint and the computational cost at inference, facilitating the deployment of resource-hungry models. However, the parameter perturbations caused by this transformation result in behavioralbehavioral disparitiesdisparities between the model before and after quantization. For example, a quantized model can misclassify some test-time samples that are otherwise classified correctly. It is not known whether such differences lead to a new security vulnerability. We hypothesize that an adversary may control this disparity to introduce specific behaviors that activate upon quantization. To study this hypothesis, we weaponize quantization-aware training and propose a new training framework to implement adversarial quantization outcomes. Following this framework, we present three attacks we carry out with quantization: (i) an indiscriminate attack for significant accuracy loss; (ii) a targeted attack against specific samples; and (iii) a backdoor attack for controlling the model with an input trigger. We further show that a single compromised model defeats multiple quantization schemes, including robust quantization techniques. Moreover, in a federated learning scenario, we demonstrate that a set of malicious participants who conspire can inject our quantization-activated backdoor. Lastly, we discuss potential counter-measures and show that only re-training consistently removes the attack artifacts. Our code is available at https://github.com/Secure-AI-Systems-Group/Qu-ANTI-zation

Keywords

Cite

@article{arxiv.2110.13541,
  title  = {Qu-ANTI-zation: Exploiting Quantization Artifacts for Achieving Adversarial Outcomes},
  author = {Sanghyun Hong and Michael-Andrei Panaitescu-Liess and Yiğitcan Kaya and Tudor Dumitraş},
  journal= {arXiv preprint arXiv:2110.13541},
  year   = {2021}
}

Comments

Accepted to NeurIPS 2021 [Poster]

R2 v1 2026-06-24T07:11:33.609Z