1. The SMART Way to Migrate Replicated Stateful Services
Jacob R. Lorch, Atul Adya, Bill Bolosky, Ronnie Chaiken, John Douceur, Jon Howell
Microsoft Research
First EuroSys Conference
19 April 2006

2. Replicated stateful services Replicated stateful servicesB
Paxos
Problem: Machine failure leads to unavailability
Solution: Replicate the service for fault tolerance
Problem: Replica state can become inconsistent
Solution: Use replicated state machine approach
The SMART Way to Migrate Replicated Stateful Services

3. Migrating replicated servicesB C D E
Migration: Changing the configuration – the set of machines running replicas
Uses of migration
Replace failed machines for long-term fault tolerance
Load balancing
Increasing or decreasing number of replicas
The SMART Way to Migrate Replicated Stateful Services

4. Limitations of current approaches
Limitations of current approaches addressed by SMART
Limitations of current approaches
Can remove non-failed machines
Enables autonomic migration, i.e., migration without human involvement
Enables load balancing
Can do concurrent request processing
Can perform arbitrary migrations, even ones replacing entire configuration
Completely described in our paper
Cannot remove non-failed machines without creating window of vulnerability
Can only remove known-failed machines
Cannot use migration for load balancing
Cannot process requests in parallel
The SMART Way to Migrate Replicated Stateful Services

5. The SMART Way to Migrate Replicated Stateful Services
Outline
Introduction
Background on Paxos
Limitations of existing approaches
SMART: Service Migration And Replication Technique
Configuration-specific replicas
Shared execution modules
Implementation and evaluation
Conclusions
The SMART Way to Migrate Replicated Stateful Services

6. The SMART Way to Migrate Replicated Stateful Services
Background on Paxos
The SMART Way to Migrate Replicated Stateful Services

7. Background: Paxos overview
protocol A B C … … …
requests:
slots: 1 2 3 4 5 6 1 2 3 4 5 6 1 2 3 4 5 6
Goal: Every service replica runs the same sequence of requests
Deterministic service ensures state changes and replies are consistent
Approach: Paxos assigns requests to virtual “slots”
No two replicas assign different requests to same slot
Each replica executes requests in slot order
The SMART Way to Migrate Replicated Stateful Services

8. Background: Paxos protocolZ A B C
PROPOSE
DECIDED
PROPOSE
DECIDED
LOGGED
LOGGED
Req
client
server replicas
One replica is the leader
Clients send requests to the leader
Leader proposes a request by sending PROPOSE message to all replicas
Each replica logs it and sends a LOGGED message to the leader
When leader receives LOGGED messages from a majority, it decides it and sends a DECIDED message
The SMART Way to Migrate Replicated Stateful Services

9. Background: Paxos leader change
Poll
Poll
Reply
If leader fails, another replica “elects” itself
New leader must poll replicas and hear replies from a majority
Ensures it learns enough about previous leaders’ actions to avoid conflicting proposals
The SMART Way to Migrate Replicated Stateful Services

10. Background: Paxos migrationα
Service
state A 79 80 81 82 83 84 85 B 79 80 81 82 83 84 85 C 79 80 81 82 83
A, B, C
A, B, D D 84 85
Service state includes current configuration
Request that changes that part of the state migrates the service
Configuration after request n responsible for requests n+α and beyond
The SMART Way to Migrate Replicated Stateful Services

11. The SMART Way to Migrate Replicated Stateful Services
Rationale for α Z A B C
Req
Req
PROPOSE
PROPOSE
LOGGED
LOGGED
With α=1, slot n can change the configuration responsible for slot n+1
Leader can’t propose slot n+1 until n is decided
Doesn’t know who to make proposal to, let alone whether it can make proposal at all
Prevents pipelining of requests
Request may wait a network round trip and a disk write
The SMART Way to Migrate Replicated Stateful Services

12. Limitations of existing approaches
The SMART Way to Migrate Replicated Stateful Services

13. The SMART Way to Migrate Replicated Stateful Services
No request pipelining
Leader change is complicated
How to ensure that new leader knows the right configuration to poll?
How to handle some outstanding proposals being from one configuration and some from another?
Other problems
To avoid this complexity, current approaches use α=1
But, this prevents request pipelining
The SMART Way to Migrate Replicated Stateful Services

14. Window of vulnerabilityC D
Poll
Poll
DECIDED
PROPOSE
DECIDED
PROPOSE
LOGGED
LOGGED
Removing a machine creates window of vulnerability
Effectively, it induces a failure of the removed replica
Consequently, service can become permanently unavailable even if less than half the machines fail
Considered acceptable since machines only removed when known to a human to have permanently failed
Not suitable for autonomic migration using imperfect failure detectors, or for load balancing
The SMART Way to Migrate Replicated Stateful Services

15. The SMART Way to Migrate Replicated Stateful Services

16. Configuration-specific replicas
Replica 1A
Replica 1B
Replica 1C
Replica 2A
Replica 2B
Replica 2D A B C D
Each configuration has its own set of replicas and its own separate instance of Paxos
Simplifies leader change so we can pipeline requests
Election always happens in a static configuration
No window of vulnerability because a replica can remain alive until next configuration is established
The SMART Way to Migrate Replicated Stateful Services

17. SMART migration protocol
Replica 1A
FINISHED
FINISHED
FINISHED
FINISHED
FINISHED
FINISHED
JOIN
JOIN
JOIN
Replica 1B
FINISHED
FINISHED
FINISHED
FINISHED
FINISHED
FINISHED
Replica 1C
FINISHED
FINISHED
FINISHED
FINISHED
FINISHED
FINISHED
Replica 2A
READY
READY
READY
Replica 2B
PREPARE
READY
READY
READY
JOIN
Replica 2D A B C
JOIN-REQ D
After creating new configuration, send JOIN msgs
After executing request n+α-1, send FINISHED msgs
Tells new replicas where they can get starting state
Makes up for possibly lost JOIN messages
When a majority of successor configuration have their starting state, replica kills itself
If a machine misses this phase, it can still join later
The SMART Way to Migrate Replicated Stateful Services

18. Shared execution modules
Agreement 1A
Replica 1A
Replica 1B
Agreement 1B
Agreement 1C
Replica 1C
Execution 1A
Execution 1B
Execution 1C
Agreement 2A
Replica 2A
Agreement 2B
Replica 2B
Agreement 2D
Replica 2D
Execution 2A
Execution 2B
Execution 2D
Execution
Execution
Execution
Execution A B C D
Configuration-specific replicas have a downside
One copy of service state for each replica
Need to copy state to new replicas
Solution: Shared execution modules
Divide replica into agreement and execution modules
One execution module for all replicas on machine
The SMART Way to Migrate Replicated Stateful Services

19. Implementation and evaluation
SMART implemented in a replicated state machine library, LibSMART
Lets you build a service as if it were single-machine, then turns it into a replicated, migratable service
Farsite distributed file system service ported to LibSMART
Straightforward because LibSMART uses BFT interface
Experimental results using simple key/value service
Pipelining reduces average client latency by 14%
Migration happens quickly, so clients only see a bit of extra latency, less than 30 ms
The SMART Way to Migrate Replicated Stateful Services

20. The SMART Way to Migrate Replicated Stateful Services
Conclusions
Migration is useful for replicated services
Long-term fault tolerance, load balancing
Current approaches to migration have limitations
SMART removes these limitations by using configuration-specific replicas
Can remove live machines, enabling autonomic migration and load balancing
Can overlap processing of concurrent requests
SMART is practical
Implementation supports large, complex file system service
The SMART Way to Migrate Replicated Stateful Services