Chasing the Speed of Light: Low-Latency Planetary-Scale Adaptive Byzantine Consensus

Blockchain technology has sparked renewed interest in planetary-scale Byzantine fault-tolerant (BFT) state machine replication (SMR). While recent works have mainly focused on improving the scalability and throughput of these protocols, few have addressed latency. We present FlashConsensus, a novel transformation for optimizing the latency of quorum-based BFT consensus protocols. FLASHCONSENSUS uses an adaptive resilience threshold that enables faster transaction ordering when the system contains few faulty replicas. Our construction exploits adaptive weighted replication to automatically assign high voting power to the fastest replicas, forming small quorums that significantly speed up consensus. Even when using such quorums with a smaller resilience threshold, FlashConsensus still satisfies the standard SMR safety and liveness guarantees with optimal resilience, thanks to the judicious integration of abortable SMR and BFT forensics techniques. Our experiments with tens of replicas spread in all continents show that FLASHCONSENSUS can order transactions with finality in less than 0.4s, half the time of a PBFT-like protocol (with optimal consensus latency) in the same network, and matching the latency of this protocol running on the theoretically best possible internet links (transmitting at 67% of the speed of light).