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Dettagli Bibliografici
Autori principali: Refael, Yehonathan, Hakim, Adam, Greenberg, Lev, Lokam, Satya, Aviv, Tal, Fishman, Ben, Seidman, Shachar, Jain, Racchit, Tenenbaum, Jay
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2407.10886
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author Refael, Yehonathan
Hakim, Adam
Greenberg, Lev
Lokam, Satya
Aviv, Tal
Fishman, Ben
Seidman, Shachar
Jain, Racchit
Tenenbaum, Jay
author_facet Refael, Yehonathan
Hakim, Adam
Greenberg, Lev
Lokam, Satya
Aviv, Tal
Fishman, Ben
Seidman, Shachar
Jain, Racchit
Tenenbaum, Jay
contents Large language models (LLMs) have recently seen widespread adoption in both academia and industry. As these models grow, they become valuable intellectual property (IP), reflecting substantial investments by their owners. The high cost of cloud-based deployment has spurred interest in running models on edge devices, but this risks exposing parameters to theft and unauthorized use. Existing approaches to protect model IP on the edge trade off practicality, accuracy, or deployment requirements. We introduce SLIP, a hybrid inference algorithm designed to protect edge-deployed models from theft. SLIP is, to our knowledge, the first hybrid protocol that is both practical for real-world applications and provably secure, while incurring zero accuracy degradation and minimal latency overhead. It partitions the model across two computing resources: one secure but expensive, and one cost-effective but vulnerable. Using matrix decomposition, the secure resource retains the most sensitive portion of the model's IP while performing only a small fraction of the computation; the vulnerable resource executes the remainder. The protocol includes security guarantees that prevent attackers from using the partition to infer the protected information. Finally, we present experimental results that demonstrate the robustness and effectiveness of our method, positioning it as a compelling solution for protecting LLMs.
format Preprint
id arxiv_https___arxiv_org_abs_2407_10886
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle SLIP: Securing LLMs IP Using Weights Decomposition
Refael, Yehonathan
Hakim, Adam
Greenberg, Lev
Lokam, Satya
Aviv, Tal
Fishman, Ben
Seidman, Shachar
Jain, Racchit
Tenenbaum, Jay
Cryptography and Security
Machine Learning
Large language models (LLMs) have recently seen widespread adoption in both academia and industry. As these models grow, they become valuable intellectual property (IP), reflecting substantial investments by their owners. The high cost of cloud-based deployment has spurred interest in running models on edge devices, but this risks exposing parameters to theft and unauthorized use. Existing approaches to protect model IP on the edge trade off practicality, accuracy, or deployment requirements. We introduce SLIP, a hybrid inference algorithm designed to protect edge-deployed models from theft. SLIP is, to our knowledge, the first hybrid protocol that is both practical for real-world applications and provably secure, while incurring zero accuracy degradation and minimal latency overhead. It partitions the model across two computing resources: one secure but expensive, and one cost-effective but vulnerable. Using matrix decomposition, the secure resource retains the most sensitive portion of the model's IP while performing only a small fraction of the computation; the vulnerable resource executes the remainder. The protocol includes security guarantees that prevent attackers from using the partition to infer the protected information. Finally, we present experimental results that demonstrate the robustness and effectiveness of our method, positioning it as a compelling solution for protecting LLMs.
title SLIP: Securing LLMs IP Using Weights Decomposition
topic Cryptography and Security
Machine Learning
url https://arxiv.org/abs/2407.10886