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An Introduction to Consensus with Raft

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1 An Introduction to Consensus with Raft
Diego Ongaro John Ousterhout Stanford University

2 Raft Consensus Algorithm
April 2014 Raft Consensus Algorithm

3 availability or consistency
Distributed Systems availability or consistency April 2014 Raft Consensus Algorithm

4 Inside a Consistent System
TODO: eliminate single point of failure An ad hoc algorithm “This case is rare and typically occurs as a result of a network partition with replication lag.” Watch out – OR – A consensus algorithm (built-in or library) Paxos, Raft, … A consensus service ZooKeeper, etcd, consul, … April 2014 Raft Consensus Algorithm

5 Raft Consensus Algorithm
What is Consensus? Agreement on shared state (single system image) Recovers from server failures autonomously Minority of servers fail: no problem Majority fail: lose availability, retain consistency Servers April 2014 Raft Consensus Algorithm

6 Why Is Consensus Needed?
Key to building consistent storage systems Top-level system configuration Which server is my SQL master? What shards exist in my storage system? Which servers store shard X? Sometimes used to replicate entire database state (e.g., Megastore, Spanner) April 2014 Raft Consensus Algorithm

7 Raft Consensus Algorithm
Goal: Replicated Log Clients z6 Log Consensus Module State Machine Log Consensus Module State Machine Consensus Module State Machine x 1 y 2 z 6 x 1 y 2 z 6 x 1 y 2 z 6 Servers Log x3 y2 x1 z6 x3 y2 x1 z6 x3 y2 x1 z6 Replicated log  replicated state machine All servers execute same commands in same order Consensus module ensures proper log replication System makes progress as long as any majority of servers are up Failure model: fail-stop (not Byzantine), delayed/lost messages April 2014 Raft Consensus Algorithm

8 Raft Consensus Algorithm
Paxos Protocol Leslie Lamport, 1989 Nearly synonymous with consensus Hard to understand “The dirty little secret of the NSDI community is that at most five people really, truly understand every part of Paxos ;-).” – Anonymous NSDI reviewer Bad foundation for building systems “There are significant gaps between the description of the Paxos algorithm and the needs of a real-world system…the final system will be based on an unproven protocol.” – Chubby authors April 2014 Raft Consensus Algorithm

9 Raft’s Design for Understandability
We wanted the best algorithm for building real systems Must be correct, complete, and perform well Must also be understandable “What would be easier to understand or explain?” Fundamentally different decomposition than Paxos Less complexity in state space Less mechanism April 2014 Raft Consensus Algorithm

10 Raft Consensus Algorithm
User study Quiz Grades Survey Results April 2014 Raft Consensus Algorithm

11 Raft Consensus Algorithm
Raft Overview Leader election Select one of the servers to act as leader Detect crashes, choose new leader Log replication (normal operation) Leader takes commands from clients, appends them to its log Leader replicates its log to other servers (overwriting inconsistencies) Safety Only elect leaders with all committed entries in their logs April 2014 Raft Consensus Algorithm

12 Server States At any given time, each server is either: Follower
Follower: completely passive replica (issues no RPCs, responds to incoming RPCs) Candidate: used to elect a new leader Leader: handles all client interactions, log replication At most one viable leader at a time time out, start election receive votes from majority of servers start Follower Candidate Leader April 2014 Raft Consensus Algorithm

13 Raft Consensus Algorithm
Terms Term 1 Term 2 Term 3 Term 4 Term 5 time Elections Split Vote Normal Operation Time divided into terms: Election Normal operation under a single leader At most one leader per term Each server maintains current term value Key role of terms: identify obsolete information April 2014 Raft Consensus Algorithm

14 Leader Election Leaders send heartbeats to maintain authority.
Upon election timeout, start new election: Increment current term Change to Candidate state Vote for self Send Request Vote RPCs to all other servers, wait until either: Receive votes from majority of servers: Become leader, send heartbeats to all other servers Receive RPC from valid leader: Return to follower state No-one wins election (election timeout elapses): Increment term, start new election

15 Leader Election Visualization
The Secret Lives of Data Visualizes distributed algorithms, starting with Raft Project by Ben Johnson (author of go-raft) April 2014 Raft Consensus Algorithm

16 Randomized Timeouts If we choose election timeouts randomly,
One server usually times out and wins election before others wake up

17 Raft Consensus Algorithm
Raft Paper Log replication Client interaction Cluster membership changes Log compaction To appear: 2014 USENIX Annual Technical Conf. June in Philadelphia Draft on Raft website April 2014 Raft Consensus Algorithm

18 Raft Consensus Algorithm
Raft Implementations kanaka/raft.js JS Joel Martin go-raft Go Ben Johnson (Sky) and Xiang Li (CoreOS) hashicorp/raft Armon Dadgar (HashiCorp) LogCabin C++ Diego Ongaro (Stanford) ckite Scala Pablo Medina peterbourgon/raft Peter Bourgon rafter Erlang Andrew Stone (Basho) barge Java Dave Rusek py-raft Python Toby Burress ocaml-raft OCaml Heidi Howard (Cambridge) April 2014 Raft Consensus Algorithm

19 Best Logo: go-raft by Brandon Philips (CoreOS) April 2014
Raft Consensus Algorithm

20 Summary Consensus is key to building consistent systems
Design for understandability Raft separates leader election from log replication Leader election uses voting and randomized timeouts More at Paper draft, other talks 10 to 50+ implementations raft-dev mailing list Diego Ongaro @ongardie

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