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[ICLR22] "How to Robustify Black-Box ML Models? A Zeroth-Order Optimization Perspective" by Yimeng Zhang, Yuguang Yao, Jinghan Jia, Jinfeng Yi, Mingyi Hong, Shiyu Chang, Sijia Liu

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Black-Box-Defense

This repository contains the code and models necessary to replicate the results of our recent paper:

How to Robustify Black-Box ML Models? A Zeroth-Order Optimization Perspective
Yimeng Zhang, Yuguang Yao, Jinghan Jia, Jinfeng Yi, Mingyi Hong, Shiyu Chang, Sijia Liu

ICLR'22 (Spotlight)
Paper: https://openreview.net/forum?id=W9G_ImpHlQd

We formulate the problem of black-box defense (as shown in Fig. 1) and investigate it through the lens of zeroth-order (ZO) optimization. Different from existing work, our paper aims to design the restriction-least black-box defense and our formulation is built upon a query-based black-box setting, which avoids the use of surrogate models.

We propose a novel black-box defense approach, ZO AutoEncoder-based Denoised Smoothing (ZO-AE-DS) as shown in Fig. 3, which is able to tackle the challenge of ZO optimization in high dimensions and convert a pre-trained non-robust ML model into a certifiably robust model using only function queries.

To train ZO-AE-DS, we adopt a two-stage training protocol. 1) White-box pre-training on AE: At the first stage, we pre-train the AE model by calling a standard FO optimizer (e.g., Adam) to minimize the reconstruction loss. The resulting AE will be used as the initialization of the second-stage training. We remark that the denoising model can also be pre-trained. However, such a pre-training could hamper optimization, i.e., making the second-stage training over θ easily trapped at a poor local optima. 2) End-to-end training: At the second stage, we keep the pre-trained decoder intact and merge it into the black-box system.

The performance comparisons with baselines are shown in Table 2.

Overview of the Repository

Our code is based on the open source codes of Salmanet al.(2020). Our repo contains the code for our experiments on MNIST, CIFAR-10, STL-10, and Restricted ImageNet.

Let us dive into the files:

  1. train_classifier.py: a generic script for training ImageNet/Cifar-10 classifiers, with Gaussian agumentation option, achieving SOTA.
  2. AE_DS_train.py: the main code of our paper which is used to train the different AE-DS/DS model with FO/ZO optimization methods used in our paper.
  3. AE_DS_certify.py: Given a pretrained smoothed classifier, returns a certified L2-radius for each data point in a given dataset using the algorithm of Cohen et al (2019).
  4. architectures.py: an entry point for specifying which model architecture to use per classifiers, denoisers and AutoEncoders.
  5. archs/ contains the network architecture files.
  6. trained_models/ contains the checkpoints of AE-DS and base classifiers.

Getting Started

  1. git clone https://github.com/damon-demon/Black-Box-Defense.git

  2. Install dependencies:

    conda create -n Black_Box_Defense python=3.6
    conda activate Black_Box_Defense
    conda install numpy matplotlib pandas seaborn scipy==1.1.0
    conda install pytorch torchvision cudatoolkit=10.0 -c pytorch # for Linux
    
  3. Train a AE-DS model using Coordinate-Wise Gradient Estimation (CGE) for ZO optimization on CIFAR-10 Dataset.

    python3 AE_DS_train.py --model_type AE_DS --lr 1e-3 --outdir ZO_AE_DS_lr-3_q192_Coord --dataset cifar10 --arch cifar_dncnn --encoder_arch cifar_encoder_192_24 --decoder_arch cifar_decoder_192_24 --epochs 200 --train_method whole --optimization_method ZO --zo_method CGE --pretrained-denoiser $pretrained_denoiser  --pretrained-encoder $pretrained_encoder --pretrained-decoder $pretrained_decoder --classifier $pretrained_clf --noise_sd 0.25  --q 192
    
  4. Certify the robustness of a AE-DS model on CIFAR-10 dataset.

    python3 AE_DS_certify.py --dataset cifar10 --arch cifar_dncnn --encoder_arch cifar_encoder_192_24 --decoder_arch cifar_decoder_192_24 --base_classifier $pretrained_base_classifier --pretrained_denoiser $pretrained_denoiser  --pretrained-encoder $pretrained_encoder --pretrained-decoder $pretrained_decoder --sigma 0.25 --outfile ZO_AE_DS_lr-3_q192_Coord_NoSkip_CF_result/sigma_0.25 --batch 400 --N 10000 --skip 1 --l2radius 0.25
    

Check the results in ZO_AE_DS_lr-3_q192_Coord_NoSkip_CF_result/sigma_0.25.

Citation

@inproceedings{
zhang2022how,
title={How to Robustify Black-Box {ML} Models? A Zeroth-Order Optimization Perspective},
author={Yimeng Zhang and Yuguang Yao and Jinghan Jia and Jinfeng Yi and Mingyi Hong and Shiyu Chang and Sijia Liu},
booktitle={International Conference on Learning Representations},
year={2022},
url={ https://openreview.net/forum?id=W9G_ImpHlQd }
}

Contact

For more information, contact Yimeng(Damon) Zhang with any additional questions or comments.

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[ICLR22] "How to Robustify Black-Box ML Models? A Zeroth-Order Optimization Perspective" by Yimeng Zhang, Yuguang Yao, Jinghan Jia, Jinfeng Yi, Mingyi Hong, Shiyu Chang, Sijia Liu

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