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Secure Software Leasing Without Assumptions

Quantum Physics 2023-04-04 v1

Abstract

Quantum cryptography is known for enabling functionalities that are unattainable using classical information alone. Recently, Secure Software Leasing (SSL) has emerged as one of these areas of interest. Given a target circuit CC from a circuit class, SSL produces an encoding of CC that enables a recipient to evaluate CC, and also enables the originator of the software to verify that the software has been returned -- meaning that the recipient has relinquished the possibility of any further use of the software. Clearly, such a functionality is unachievable using classical information alone, since it is impossible to prevent a user from keeping a copy of the software. Recent results have shown the achievability of SSL using quantum information for a class of functions called compute-and-compare (these are a generalization of the well-known point functions). These prior works, however all make use of setup or computational assumptions. Here, we show that SSL is achievable for compute-and-compare circuits without any assumptions. Our technique involves the study of quantum copy-protection, which is a notion related to SSL, but where the encoding procedure inherently prevents a would-be quantum software pirate from splitting a single copy of an encoding for CC into two parts, each of which enables a user to evaluate CC. We show that point functions can be copy-protected without any assumptions, for a novel security definition involving one honest and one malicious evaluator; this is achieved by showing that from any quantum message authentication code, we can derive such an honest-malicious copy-protection scheme. We then show that a generic honest-malicious copy-protection scheme implies SSL; by prior work, this yields SSL for compute-and-compare functions.

Keywords

Cite

@article{arxiv.2101.12739,
  title  = {Secure Software Leasing Without Assumptions},
  author = {Anne Broadbent and Stacey Jeffery and Sébastien Lord and Supartha Podder and Aarthi Sundaram},
  journal= {arXiv preprint arXiv:2101.12739},
  year   = {2023}
}

Comments

41 pages, 5 figures

R2 v1 2026-06-23T22:39:57.572Z