International Association for Cryptologic Research (IACR)
Abstract
The Snowden\u27s revelations kick-started a community-wide effort to develop cryptographic tools against mass surveillance.
In this work, we propose to add another primitive to that toolbox: Fail-Stop Signatures (FSS) [EC\u2789].
FSS are digital signatures enhanced with a forgery-detection mechanism that can protect a PPT signer from more powerful attackers.
Despite the fascinating concept, research in this area stalled after the \u2790s. However, the ongoing transition to post-quantum cryptography, with its hiccups due to the novelty of underlying assumptions, has become the perfect use case for FSS.
This paper aims to reboot research on FSS with practical use in mind: Our framework for FSS includes ``fine-grained\u27\u27 security definitions (that assume a powerful, but bounded adversary e.g: can break 128-bit of security, but not 256-bit).
As an application, we show new FSS constructions for the post-quantum setting.
We show that FSS are equivalent to standard, provably secure digital signatures that do not require rewinding or programming random oracles, and that this implies lattice-based FSS.
Our main construction is an FSS version of SPHINCS, which required building FSS versions of all its building blocks: WOTS, XMSS, and FORS.
In the process, we identify and provide generic solutions for two fundamental issues arising when deriving a large number of private keys from a single seed, and when building FSS for Hash-and-Sign-based signatures
