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minimum code implementation for our USENIX paper `On the Security Risks of AutoML`.

Project description

This project is a minimized runnable project cut from trojanzoo, which contains more datasets, models, attacks and defenses. This repo will not be maintained.

This is a minimum code implementation of our USENIX'22 paper On the Security Risks of AutoML.

python>=3.9 License

pypi docker

Abstract

The artifact discovers the vulnerability gap between manual models and automl models against various kinds of attacks (adversarial, poison, backdoor, extraction and membership) in image classification domain. It implements all datasets, models, and attacks used in our paper.
We expect the artifact could support the paper's claim that automl models are more vulnerable than manual models against various kinds of attacks, which could be explained by their small gradient variance.

Checklist

  • Binary: on pypi with any platform.
  • Model: Our pretrained models are available on Google Drive (link). Follow the model path style {model_dir}/image/{dataset}/{model}.pth to place them in correct location.
  • Data set: CIFAR10, CIFAR100 and ImageNet32.
    Use --download flag to download them automatically at first running.
    ImageNet32 requires manual set-up at their website due to legality.
  • Run-time environment:
    At any platform (Windows and Ubuntu tested).
    Pytorch and torchvision required. (CUDA 11.3 recommended)
    adversarial-robustness-toolbox required for extraction attack and membership attack.
  • Hardware: GPU with CUDA support is recommended.
  • Execution: Model training and backdoor attack would be time-consuming. It would cost more than half day on a Nvidia Quodro RTX6000.
  • Metrics: Model accuracy, attack success rate, clean accuracy drop and cross entropy.
  • Output: console output and saved model files (.pth).
  • Experiments: OS scripts. Recommend to run scripts 3-5 times to reduce the randomness of experiments.
  • How much disk space is required (approximately):
    less than 5GB.
  • How much time is needed to prepare workflow (approximately): within 1 hour.
  • How much time is needed to complete experiments (approximately): 3-4 days.
  • Publicly available: on GitHub.
  • Code licenses: GPL-3.
  • Archived: GitHub commit ff315234561602203615d11166f8f346b4f29dd4.

Description

How to access

Hardware Dependencies

Recommend to use GPU with CUDA 11.3 and CUDNN 8.0.
Less than 5GB disk space is needed.

Software Dependencies

You need to install python==3.9, pytorch==1.10.x, torchvision==0.11.x manually.

ART (IBM) is required for extraction attack and membership attack.
pip install adversarial-robustness-toolbox

Data set

We use CIFAR10, CIFAR100 and ImageNet32 datasets.
Use --download flag to download them automatically at first running.
ImageNet32 requires manual set-up at their website due to legality.

Models

Our pretrained models are available on Google Drive (link). Follow the model path style {model_dir}/image/{dataset}/{model}.pth to place them in correct location.

Installation

(optional) Config Path

You can set the config files to customize data storage location and many other default settings. View /configs_example as an example config setting.
We support 3 configs (priority ascend):

  • package:
    (DO NOT MODIFY)
    autovul/base/configs/*.yml
    autovul/vision/configs/*.yml
  • user:
    ~/.autovul/configs/base/*.yml
    ~/.autovul/configs/vision/*.yml
  • workspace:
    ./configs/base/*.yml
    ./configs/vision/*.yml

Experiment Workflow

Bash Files

Check the bash files under /bash to reproduce our paper results.

Train Models

You need to first run /bash/train.sh to get pretrained models.
If you run it for the first time, please run with --download flag to download the dataset:
bash ./bash/train.sh "--download"

It takes a relatively long time to train all models, here we provide our pretrained models on Google Drive (link). Follow the model path style {model_dir}/image/{dataset}/{model}.pth to place them in correct location.

Run Attacks

/bash/adv_attack.sh
/bash/poison.sh
/bash/backdoor.sh
/bash/extraction.sh
/bash/membership.sh

Run Other Exps

/bash/grad_var.sh
/bash/mitigation_backdoor.sh
/bash/mitigation_extraction.sh

For mitigation experiments, the architecture names in our paper map to:

  • darts-i: diy_deep
  • darts-ii: diy_no_skip
  • darts-iii: diy_deep_noskip

These are the 3 options for --model_arch {arch} (with --model darts)

Evaluation and Expected Result

Our paper claims that automl models are more vulnerable than manual models against various kinds of attacks, which could be explained by low gradient variance.

Training

(Table 1) Most models around 96%-97% accuracy on CIFAR10.

Attack

For automl models on CIFAR10,

  • adversarial
    (Figure 2) higher success rate around 10% (±4%).
  • poison
    (Figure 6) lower accuracy drop around 5% (±2%).
  • backdoor
    (Figure 7) higher success rate around 2% (±1%) lower accuracy drop around 1% (±1%).
  • extraction
    (Figure 9) lower inference cross entropy around 0.3 (±0.1).
  • membership
    (Figure 10) higher auc around 0.04 (±0.01).

Others

  • gradient variance
    (Figure 12) automl with lower gradient variance (around 2.2).
  • mitigation architecture
    (Table 4, Figure 16, 17) deep architectures (darts-i, darts-iii) have larger cross entropy for extraction attack (around 0.5), and higher accuracy drop for poisoning attack (around 7%).
    To increase cell depth, we may re-wire existing models generated by NAS or modify the performance measure of candidate models. For the former case, we have provided the script to rewire a given model (link). Note that it is necessary to ensure the re-wiring doesn't cause a significant performance drop. For the latter case, we may increase the number of training steps in the single-step gradient descent used in DARTS.
    To suppress skip connects, we replace the skip connects in a given model with other operations (e.g., convolution) or modify the likelihood of them being selected in the search process. Fro the former case, we have provided the script to substitute skip connects with convolution operations (link). Note that it is necessary to ensure the substitution doesn't cause a significant performance drop. For the latter case, we may multiply the weight of skip connect $\alpha_\mathrm{skip}$ by a coefficient $\gamma \in (0, 1)$.
  • loss contours
    Take the parameter-space contour as an example. We pick the parameters of the first convolutional layer and randomly generate two orthogonal directions $d_1$ and $d_2$ in the parameter space. For simplicity, we set all each dimension of $d_1$ and $d_2$ to be either $+1$ or $-1$ in a random order and ensure that their orthogonality as $d_1 \cdot d_2 = 0$. We then follow Equation (12) in the paper to explore the mesh grid of $[-0.5, 0.5] \times [-0.5, 0.5]$ and plot the loss contour. A similar procedure is applied to plot the loss contour in the input space, but with the grid set as $[-0.2, 0.2] \times [-0.2, 0.2]$

Experiment Customization

Use -h or --help flag for example python files to check available arguments.

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