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Peer-to-Peer Systems

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Title: Peer-to-Peer Systems


1
Peer-to-Peer Systems
  • Rodrigo Rodrigues
  • Peter Druschel
  • Max Planck Institute for Software Systems

2
Paper Overview
  • Survey paper
  • Long list of references
  • Presents a high view of various aspects of P2P
    systems
  • Describes distributed hash tables in more detail

3
In the beginning
  • 1999
  • Napster music sharing system
  • Gave a bad reputation to P2P systems
  • Freenet anonymous data store
  • SETI_at_home volunteer-based distributed
    computational project

4
Now
  • BitTorrent
  • Skype P2P telephony system
  • Skinkers enterprise communication management
    system
  • P2PLive, CoolStreaming, BBCs iPlayer

5
What I think
  • Previous list mentioned commercial products
  • Does it mean all major issues have been solved?

6
Email from Skype
  • To our valued customersAs 2010 draws to a
    close, I would like to take a moment to thank
    each of you for your patience, understanding, and
    support during Skypes recent outage.
  • Kind regards, Tony BatesCEOSkype

7
Defining propertiesof P2P systems
  • High degree of decentralization
  • Few or no dedicated central nodes
  • Multiple administrative domains
  • Low barriers to deployment
  • Organic growth
  • Resilience to faults and attacks
  • Abundance and diversity of resources

8
What I think
  • P2P systems are
  • Very cheap
  • Very easy to deploy
  • Highly scalable

9
Applications (I)
  • Sharing and distributing files
  • Napster (quickly shutdown)
  • Gnutella, FastTrack aka Kazaa(all
    decentralized)
  • eDonkey, BitTorrent (faster)
  • Streaming media
  • PPLive, Coolstreaming (academia)
  • BBCs iPlayer, Skinkers Livestation (industry)

10
Applications (II)
  • Telephony
  • Skype
  • Scientific Computing
  • SETI_at_home
  • BOINC
  • Other
  • Distributed storage systems (Freenet)
  • Content-delivery networks(CoralCDN, CoDeeN)

11
Typology (I)
  • Degree of centralization
  • Partly decentralized
  • BitTorrent tracker,
  • Skype billing subsystem
  • Fully decentralized
  • More scalable
  • Resilient to failure, attacks and legal
    challenges
  • Can have supernodes

12
Typology (II)
  • Overlay maintenance
  • Overlay is graph G (N, E) describing set of
    links E among members of set N of participating
    nodes
  • If there is a link in E between two nodes, they
    are aware of each other
  • Overlays can be structured or unstructured

13
Unstructured overlays
  • When a node joins, it acquires a set of
    "neighbors" by
  • Contacting the tracker (BitTorrent)
  • Contacting a system participant
  • Must have a mechanism advertising these nodes

14
Structured overlays (I)
  • Use key-based routing
  • Each node has a unique identifier
  • 160-bit integer
  • Identifiers are uniformly distributed
  • Addressing is based on keys
  • Each key is mapped into exactly one of the
    current overlay nodes
  • Smallest integer "larger" than key value make
    identifier space circular

15
Structured overlays (II)
  • Key-based routing implements primitiveKBR(no, k)
    that produces a path going from a node no to the
    node holding key k
  • Big tradeoff is between
  • Keeping paths short
  • Minimizing state information kept by nodes

16
Typology (III)
  • Distributed state
  • In partly decentralized systems state is
    maintained by
  • The central node(s)
  • The peers assigned by it/them to each node
  • In decentralized systems, state is kept by
  • The content providers
  • Individual peers

17
Locating data
  • In unstructured systems, nodes wanting to access
    a specific object flood their neighbors, which
    flood their neighbors and so on
  • Structured systems use distributed hash tables
  • All data have keys
  • Stored at node responsible for key value and
    replicated at its successors

18
Typology (IV)
  • Distributed control
  • In unstructured systems , it is typically done by
    epidemic techniques
  • Can also build a spanning tree among the nodes if
    membership is fairly stable
  • In structured systems, it is much easier to
    build spanning trees

19
Content distribution
  • Tree-based protocols
  • Main disadvantage is that leave nodes ado not
    contribute anything
  • Full binary tree of height n has 2n1- 1 nodes
    and 2n leaves
  • Swarm-based protocols
  • BitTorrent
  • All nodes can participate

20
Challenges (I)
  • Controlling membership
  • Preventing Sybil attacks
  • One node pretending to be many
  • Can require proof of work or use trusted
    identities (FARSITE)

21
Challenges (II)
  • Protecting data
  • Integrity and Authenticity
  • Can use digital signatures
  • Data stored in DHTs can be self-certifying by
    making DHT keys function of data themselves
  • Can use voting (LOCKSS)
  • Availability and Durability
  • Replicate data and keep system alive

22
Challenges (III)
  • Incentives
  • Fighting Free riding
  • Big problem
  • BitTorrent tit-for-tat
  • Not always feasible
  • Managing P2P Systems
  • Lack of centralized control can make system hard
    to manage
  • Skype collapses

23
P2P and ISPs
  • P2P systems consume a lot of bandwidth
  • Current ISP billing models assume that customers
    send much less bits than they receive
  • Flat-rate pricing for residential customers
  • Bandwidth-based pricing for information providers
  • ISPs have no way to bill anyone for P2P traffic

24
Conclusions
  • P2P is a disruptive technology with great
    potential
  • Major strength is lack of centralized control
  • Also creates new challenges that can be
  • Technical
  • Commercial
  • Legal
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