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New Findings Show All Major Art Protection Tools Are Vulnerable to AI Forgeryby@torts
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New Findings Show All Major Art Protection Tools Are Vulnerable to AI Forgery

by TortsDecember 12th, 2024
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Popular style protection tools like Glaze and Mist are ineffective against AI mimicry methods, leaving artists vulnerable to forgery. Adaptive attacks show that protections can't improve over time.
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Abstract and 1. Introduction

  1. Background and Related Work

  2. Threat Model

  3. Robust Style Mimicry

  4. Experimental Setup

  5. Results

    6.1 Main Findings: All Protections are Easily Circumvented

    6.2 Analysis

  6. Discussion and Broader Impact, Acknowledgements, and References

A. Detailed Art Examples

B. Robust Mimicry Generations

C. Detailed Results

D. Differences with Glaze Finetuning

E. Findings on Glaze 2.0

F. Findings on Mist v2

G. Methods for Style Mimicry

H. Existing Style Mimicry Protections

I. Robust Mimicry Methods

J. Experimental Setup

K. User Study

L. Compute Resources

7 Discussion and Broader Impact

Adversarial perturbations do not protect artists from style mimicry. Our work is not intended as an exhaustive search for the best robust mimicry method, but as a demonstration of the brittleness of existing protections. Because these protections have received significant attention, artists may believe they are effective. But our experiments show they are not. As we have learned from adversarial ML, whoever acts first (in this case, the artist) is at a fundamental disadvantage (Radiya-Dixit et al., 2021). We urge the community to acknowledge these limitations and think critically when performing future evaluations.


Just like adversarial examples defenses, mimicry protections should be evaluated adaptively. In adversarial settings, where one group wants to prevent another group from achieving some goal, it is necessary to consider “adaptive attacks” that are specifically designed to evade the defense (Carlini & Wagner, 2017). Unfortunately, as repeatedly seen in the literature on machine learning robustness, even after adaptive attacks were introduced, many evaluations remained flawed and defenses were broken by (stronger) adaptive attacks (Tramer et al., 2020). We show it is the same with mimicry protections: simple adaptive attacks significantly reduce their effectiveness. Surprisingly, most protections we study claim robustness against input transformations (Liang et al., 2023; Shan et al., 2023a), but minor modifications were sufficient to circumvent them.


We hope that the literature on style mimicry prevention will learn from the failings of the adversarial example literature: performing reliable, future-proof evaluations is much harder than proposing a new defense. Especially when techniques are widely publicized in the popular press, we believe it is necessary to provide users with exceptionally high degrees of confidence in their efficacy.


Protections are broken from day one, and cannot improve over time. Our most successful robust style mimicry methods rely solely on techniques that existed before the protections were introduced. Also, protections applied to online images cannot easily be changed (i.e., even if the image is perturbed again and re-uploaded, the older version may still be available in an internet archive) (Radiya-Dixit et al., 2021). It is thus challenging for a broken protection method to be fixed retroactively. Of course, an artist can apply the new tool to their images going forward, but pre-existing images with weaker protections (or none at all) will significantly boost an attacker’s success (Shan et al., 2023a).


Nevertheless, the Glaze and Mist protection tools recently received significant updates (after we had concluded our user study). Yet, we find that the newest 2.0 versions do not protect against our robust mimicry attempts either (see Appendix E and F). A future version could explicitly target the methods we studied, but this would not change the fact that all previously protected art would remain vulnerable, and that future attacks could again attempt to adaptively evade the newest protections. The same holds true for attempts to design similar protections for other data modalities, such as video (Passananti et al., 2024) or audio (Gokul & Dubnov, 2024).


Ethics and broader impact. The goal of our research is to help artists better decide how to protect their artwork and business. We do not focus on creating the best mimicry method, but rather on highlighting limitations in popular perturbation tools—especially since using these tools incurs a cost, as they degrade the quality of published art. We will disclose our results to the affected protection tools prior to publication, so that they can determine the best course of action for their users.


Further, we argue that having no protection tools is preferable to having insecure ones. Insecure protections may mislead artists to believe it is safe to release their work, enabling forgery and putting them in a worse situation than if they had been more cautious in the absence of any protection.


With respect to our paper, all the art featured in this paper comes either from historical artists, or from contemporary artists who explicitly permitted us to display their work. We hope our results will inform improved non-technical protections for artists in the era of generative AI.


Limitations and future work. A larger study with more than 10 artists and more annotators may help us better understand the difference in vulnerability across artists. The protections we study are not designed in awareness of our robust mimicry methods. However, we do not believe this limits the extent to which our general claims hold: artists will always be at a disadvantage if attackers can design adaptive methods to circumvent the protections.

Acknowledgements

We thank all the MTurkers that engaged with our tasks, especially those that provided valuable feedback during our preliminary studies to improve the survey. We thank the contemporary artists Stas Voloshin (@nulevoy) and Gregory Fromenteau (@greg-f) for allowing us to display their artwork in this paper. JR is supported by an ETH AI Center doctoral fellowship.

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Authors:

(1) Robert Honig, ETH Zurich ([email protected]);

(2) Javier Rando, ETH Zurich ([email protected]);

(3) Nicholas Carlini, Google DeepMind;

(4) Florian Tramer, ETH Zurich ([email protected]).


This paper is available on arxiv under CC BY 4.0 license.