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Lab 2 Group Communication Andreas Larsson 2011-01-31.

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1 Lab 2 Group Communication Andreas Larsson 2011-01-31

2 DSII: Group Comm.2 Overview Introduction to group communication Desired group communication Multicast communication Group membership service

3 DSII: Group Comm.3 Coordination in distributed systems Coordination is needed by distributed systems but hard to achieve: –Events happen concurrently –Communication links are not reliable –Computers can crash –New nodes can join the systems –Asynchronous environments  Need of an efficient way to coordinate a group of processes

4 DSII: Group Comm.4 A Distributed System in war: Synchronous Example Friendly fighter Radar Missile Commander Enemy missile Friend Ready to Fire Cancel AskPrepare Friendly fighter

5 DSII: Group Comm.5 A Distributed System in war: Reality Radar Missile Commander Enemy missile Friend Ready to Fire Fire AskPrepare Friendly fighter Friendly fighter

6 DSII: Group Comm.6 Group communication What is a group? –A number of processes which cooperate to provide a service. –An abstract identity to name a collection of processes. Group Communication –For coordination among processes of a group.

7 DSII: Group Comm.7 Who Needs Group Communication? Highly available servers (client-server) Database Replication Multimedia Conferencing Online Games Cluster management …

8 DSII: Group Comm.8 Distributed Web Server High availability

9 DSII: Group Comm.9 Online Game Fault-tolerance, Order

10 DSII: Group Comm.10 Different Comm. Methods Unicast –Point-to-Point Communication –Multiple copies are sent. Broadcast –One-to-All Communication –Abuse of Network Bandwidth Multicast –One-to-multiple Communication

11 DSII: Group Comm.11 Overview Introduction to group communication Desired group communication Multicast communication Group membership service

12 DSII: Group Comm.12 Desired Group Communication Name Abstraction Efficiency Delivery Guarantees Dynamic Membership  Multicast  Reliability, Ordering  Group membership service

13 DSII: Group Comm.13 Properties of Communication Ordering –Total ordering, causal ordering Failure behavior Reliability –Validity, integrity, agreement

14 DSII: Group Comm.14 Properties of Group Name of group Addresses of group members Dynamic group membership Options: –Peer group or client-server group –Closed or Open Group

15 DSII: Group Comm.15 Peer Group All the members are equal. All the members send messages to the group. All the members receive all the messages.

16 DSII: Group Comm.16 Client-Server Group Replicated servers. Clients do not care which server answers.

17 DSII: Group Comm.17 Overview Introduction to group communication Desired group communication Multicast communication Group membership service

18 DSII: Group Comm.18 Multicast communication Use network hardware support for broadcast or multicast when it is available. Send message over a distribution tree. Minimize the time and bandwidth utilization

19 DSII: Group Comm.19 Reliability Correct processes: those that never fail. Integrity A correct process delivers a message at most once. Validity A message from a correct process will be delivered by the process eventually. Agreement A message delivered by a correct process will be delivered by all other correct processes in the group.  Validity + Agreement = Liveness

20 DSII: Group Comm.20 Ordering Assumptions: a process belongs to at most one group. FIFO –if m p  m’ p, all correct processes that deliver m’ p will deliver m p (that is from the same sender) before m’ p. Causal –if m  m’, all correct processes that deliver m’ will deliver m before m’. Total –if a correct process delivers m before m’, all other correct processes that deliver m’ will deliver m before m’. p1p1 p2p2 p3p3 p1p1 p2p2 p3p3 p1p1 p2p2 p3p3

21 DSII: Group Comm.21 Examples Assumption: –Reliable one-to-one send operation (e.g. TCP) Basic multicast –Requirement: All correct processes will eventually deliver the message from a correct sender. –Implementation: B-multicast( g, m):  p  g: send( p, m); On receive( m) at p: B-deliver( m) at p.  Properties: integrity, validity.

22 DSII: Group Comm.22 Basic multicast: Agreement? 4 crash 1 2 3 Agreement X

23 DSII: Group Comm.23 Examples (cont.) Reliable multicast –Requirements: integrity, validity, agreement –Implementation: Received := {}; R-multicast( g, m) at process p: B-multicast( g, m); On B-deliver( m) at process p from process q if( m  Received) Received := Received  {m}; if( q  p) B-multicast( g, m); R-deliver( m); end if  Inefficient: each message is sent O(|g|) times to each process

24 DSII: Group Comm.24 Examples (cont.) FIFO-ordered multicast: –Assumption: a process belongs to at most one group. –Implementation: Local variables at p: S p = 1, R p [ |g| ]={0}; FO-multicast( g, m) at p: B-multicast( g, ); S p ++; On B-deliver( ) at p from q: if( S = R p [q] + 1) FO-deliver( m); R p [q] := S; else if( S > R p [q] + 1) place in the queue until S = R p [q] + 1; FO-deliver( m); R p [q] := S; end if –Your task: totally ordered multicasts.

25 DSII: Group Comm.25 Overview Introduction to group communication Desired group communication Multicast communication Group membership service

26 DSII: Group Comm.26 Group membership service Four tasks: –Interface for group membership changes –Failure detector –Membership change notification –Group address expansion Group address expansion Multicast Communication Group membership management Group partition: –Primary-partition – one partition only –Partitionable – many partiations at once

27 DSII: Group Comm.27 Group views Group views: –Lists of the current ordered group members –A new one is generated when processes join or leave/fail. View delivery –When a member is notified of a membership change –Requirements Order –if p delivers v(g)  v’(g), no other process delivers v’(g)  v(g). Integrity –if p delivers v(g), p  v(g). Non-triviality –if q joins a group and becomes indefinitely reachable from p, eventually q is always in the view p delivers.

28 DSII: Group Comm.28 View-synchronous group comm. Extend the reliable multicast semantics with group views. –Agreement Correct processes deliver the same set of messages in any given view –Validity (closed group) Correct processes always deliver the messages they send. p  v 0 (g) does not deliver m in v 0 (g)  p  v 1 (g) for processes that deliver m. –Integrity p q r (p,q,r) (q,r) X crash

29 DSII: Group Comm.29 Examples Ensemble: reliable group communication toolkit –Previous talk

30 DSII: Group Comm.30 IP-multicast Multicast: –Yes: efficiency –No: Reliability Ordering Group membership service: –Yes: Interface for group membership change Group address expansion –No: Failure detector Membership change notification IP: 224.0.0.1 - 239.255.255.255

31 DSII: Group Comm.31 References Distributed Systems: Concepts and Design by G. Coulouris et al., ISBN 0-201- 61918-0 –Section 4.5 Group Communication –Section 11.4 Multicast Communication –Section 14.2.2 Group Communication …

32 DSII: Group Comm.32 Lab 2: Construct a reliable and ordered multicast Reliable –Integrity, Validity, Agreement Ordered –All machines should agree on the order of all received messages. –Total and causal order. No membership service –Processes can still crash though!

33 The GUI DSII: Group Comm.33 Message display Debug message display Time for stress test 24-hour time format # of messages for stress test

34 The interface Provide –cast –basicreceive –basicpeerdown Use –deliver –debug –basicsend DSII: Group Comm.34

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