The Recoverable Consensus Hierarchy

Abstract

Herlihy's consensus hierarchy ranks the power of various synchronization primitives for solving consensus in a model where asynchronous processes communicate through shared memory, and may fail by halting. This paper revisits the consensus hierarchy in a model with crash-recovery failures, where the specification of consensus, called recoverable consensus in this paper, is weakened by allowing non-terminating executions when a process fails infinitely often. Two variations of this model are considered: with independent process failures, and with simultaneous (i.e., system-wide) process failures. We prove two fundamental results: (i) Test-And-Set is at level 2 of the recoverable consensus hierarchy if failures are simultaneous, and similarly for any primitive at level 2 of the traditional consensus hierarchy; and (ii) Test-And-Set drops to level 1 of the hierarchy if failures are independent, unless the number of such failures is bounded. To our knowledge, this is the first separation between the simultaneous and independent crash-recovery failure models with respect to the computability of consensus.