Paper 2025/890

SPEEDY: Caught at Last

Abstract

SPEEDY is a family of ultra-low-latency block ciphers designed by Leander et al. in 2021. In 2023, Boura et al. proposed a differential attack on the full 7-round variant, SPEEDY-7-192. However, shortly thereafter, Beyne and Neyt demonstrated that this attack was invalid, as the dominant differential characteristic it relied upon had probability zero. A similar issue affects another differential attack proposed the same year by Wang et al., which also targets SPEEDY-7-192 and suffers from the same flaw. As a result, although SPEEDY-7-192 was initially believed to be broken, it remained unbroken in practice, and the question of finding a valid attack on this cipher remained an open problem. In this work, we resolve this problem by presenting the first valid differential attack on SPEEDY-7-192. We verify the validity of our distinguisher using the quasidifferential framework. Moreover, our search for the differential distinguisher is significantly more rigorous than in the previous works, allowing us to explore a larger portion of the search space. We also fully exploit probabilistic extensions of the distinguisher to identify optimal parameters for the key recovery step. Our attack on SPEEDY-7-192 has data and time complexities of 2^{186.36} encryption calls and a memory complexity of 2^{84} 192-bit states. In addition, we present differential attacks on 4-round SPEEDY-5-192 and 5-round SPEEDY-6-192 which currently represent the best attacks against these smaller variants.