Toward Optimal-Complexity Hash-Based Asynchronous MVBA with Optimal Resilience

Abstract

Multi-valued validated Byzantine agreement (MVBA), a fundamental primitive of distributed computing, allows n processes to agree on a valid -bit value, despite t faulty processes behaving maliciously. Among hash-based solutions for the asynchronous setting with adaptive faults, the state-of-the-art HMVBA protocol achieves optimal O(n2) message complexity, (near-)optimal O(n + n2 λ n) bit complexity, and optimal O(1) time complexity. However, it only tolerates t < 15 n failures. In contrast, the best-known optimally-resilient protocol, SQ, incurs a higher bit complexity of O(n2 + n3 λ). This poses a fundamental question: Can a hash-based protocol be designed for the asynchronous setting with adaptive faults that simultaneously achieves optimal complexity and optimal resilience? This paper takes a significant step toward answering this question. Namely, we introduce Reducer, an MVBA protocol that retains HMVBA's optimal complexity while improving its resilience to t < 14 n. Like HMVBA and SQ, Reducer relies exclusively on collision-resistant hash functions. A key innovation in Reducer's design is its internal use of strong multi-valued Byzantine agreement (SMBA), a new variant of Byzantine agreement we introduce and construct, which ensures that the decided value was proposed by a correct process. To further advance resilience toward the optimal one-third bound, we then propose Reducer++, an MVBA protocol that tolerates up to t < (13 - ε)n adaptive failures, for any fixed constant ε> 0. Unlike Reducer, Reducer++ does not rely on SMBA. Instead, it employs a novel approach involving hash functions modeled as random oracles to ensure termination. Reducer++ maintains constant time complexity, quadratic message complexity, and quasi-quadratic bit complexity, with constants dependent on ε.