May 15, 2002Stanford Networking Seminar Associative Peer to Peer Networks: Harnessing Latent...
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May 15, 2002 Stanford Networking Seminar
Associative Peer to Peer Networks: Harnessing Latent
Semantics
Edith CohenAT&T Labs-research
Amos Fiat Haim KaplanTel-Aviv University
May 15, 2002 Stanford Networking Seminar
“Traditional” Client-server Web
Web server
May 15, 2002 Stanford Networking Seminar
Peer-to-peer Networks
• Harness vast resources• Scalability/Robustness
to failures/shutdowns
Distributed network for sharing content (music, video, software, etc.), where each host acts as both a server and a client
May 15, 2002 Stanford Networking Seminar
P2P Search
• Scope: ability to locate “rare” items “Find the 10th episode of Star Trek Voyager”
• Partial-match/complex queries: “Find an Indiana Jones movie”
…Or “Indiana Joens” movie…..
Overall performance of a P2P network highly depends on the efficiency and versatility of search
What features are important ?
May 15, 2002 Stanford Networking Seminar
(search in) Basic P2P Architectures
Decentralized: peers are connected by low-degree overlay network.
Partial-Matches Scop
eCentralized (Napster): central index service.
• Blind Search (Gnutella, FastTrack – Morpheus/ Kazza,…): search via flooding, multi-head random walks...
• Distributed Hash Tables (Freenet, Can, Chord,…): induced topology routed search.
May 15, 2002 Stanford Networking Seminar
Associative P2P networksRetain Gnutella’s desirable properties:• Distributed overlay network• Peers store only what they need (“common
good” at par with “own welfare”)• No tight control of topology/content• Support partial-match queriesAND• Have search scope (orders of magnitude
improvement over Gnutella)
• Make implicit use of latent semantics– Provably good on a reasonable model– Very good on simulations
May 15, 2002 Stanford Networking Seminar
P2P search framework
• Search queries are propagated on the overlay (from peer to a neighbor peer).
• When a peer receives a query, it checks if it can satisfy it; decreases hop count; and forwards it to a subset of its neighbors.
• Each search includes query and a “propagation rule”, which determines which neighbors the search is propagated to.
“DHTs” propagation rule= hash of query“Gnutella” propagation rule independent of queryAssociative propagation rules are predicates (guide rules)
May 15, 2002 Stanford Networking Seminar
Overview• What do we mean by “latent semantics” ?• Challenges in using latent semantics in P2P setting• Our proposal: search propagation via Possession
rules• Possession rules overlays• Search strategies
– Possession rules search strategies: Rapier, GAS– Models for “blind search” strategies (gnutella)
• Analysis in the Itemsets model• Experimental evaluation• More on GAS search strategy
May 15, 2002 Stanford Networking Seminar
View of P2P file sharing network
May 15, 2002 Stanford Networking Seminar
What is latent semantics?
• Peer/Item matrix is “Market Basket” dataset. Similar to buyers/items, Document/terms, Web-pages/hyperlinks, movies/viewers.
• Applications for extracting patterns from market basket data: Information Retrieval, Collaborative Filtering, Web search, Marketing, Recommendation Systems,…. (clustering, search, association rules)
Selections people make are dependent:•If you buy baby formula, you are more likely to buy diapers.•If two people loved a show, they are more likely to agree on other shows.
?? P2P search – direct queries to peers with interests that match yours
May 15, 2002 Stanford Networking Seminar
Challenges
• Overlay topology (“networking aspects”) must be coupled with search strategy (“Information Retrieval/Data-Mining”)
• “Traditional” IR and data-mining tools are not adapted to the highly distributed P2P setting. – Similarity metrics/clustering/ranking involve matrix
operations on the “market basket” data: principal component analysis (LSI), eigenvalue computations, association rules…
May 15, 2002 Stanford Networking Seminar
Possession Rules
• Rule(O): do you possess item O ?• Peer maintains a possession rule for each
item in its index (subset if index is large)• Search strategy: a sequence of possession
rules (with “hop counts”/search size limit)
Making this work:
• “Network”: How to build overlay that supports possession rules• “IR/DM”: design search strategies that use possession rules (and work!)
May 15, 2002 Stanford Networking Seminar
Possession-rules overlays
item
Rule(item) neighbors
A P11,p7,p3
B P2,p6,p9
C P13,p15,p1
D P4,p5,p10
Index of P26Rules/Items:Rule(A)Rule(B)Rule(C )Rule(D)
Peer26
Example Search Strategy of P26: 2 hops in rule(A) 4 hops in rule(B) 6 hops in rule(C )
4 hops in rule(A) 3 hops in rule(D)
May 15, 2002 Stanford Networking Seminar
Blind searching for O takes 13 probesSearching with rule(O) takes 2 probes
Rules/Items:Rule(A)Rule(B)Rule(C )Rule(D)
May 15, 2002 Stanford Networking Seminar
Possession-rule overlay
• When you find O, you often discover multiple peers that have O; when you give O, the searcher informs you of other peers with O.
• Peers that have O can find other peers that have O
• Coverage: The induced overlay on peers that satisfy each rule constitutes of large connected components.
• Small degree: Each peer participates in a limited number of rules. (yet, overall there is a large number rules), for each rule it “participates” in, the peer maintains several participating neighbors.
• Overlay and search boost each other (easy to find appropriate neighbors for each rule):
Network is “gnutella-like”, within each rule
(… can use “super-peer” overlay within each rule !!)
May 15, 2002 Stanford Networking Seminar
Search strategies• To beat blind search, associative search should
probe peers that are more likely to answer than “random peers”
Associative search:• RAPIER: Random Possession Rule – crudest
strategy• GAS: Greedy Selection – refined strategyBlind search: • Urand: (“gnutella”) all peers have same likelihood of being probed in each query• Prand: (“gnutella modified”) peers are probed proportionally to their index size (RAPIER has same bias)
May 15, 2002 Stanford Networking Seminar
RAPIER – Random Possession Rule
simplest possession-rule based strategy
RAPIER Search strategy:• Repeat until found:
– Pick a random item O from your index– Search peers that have this item (using
rule(O))
Straightforward to implement on top of a possession-rule overlay network
May 15, 2002 Stanford Networking Seminar
Analysis: Itemsets Model
• Items belong to “topics.” There are very many topics; but each peer can only select items from a fixed set of topics. Topic popularities can highly vary; but each peer has equal interest in each of “its” topics.
We show that• RAPIER is at least as good as Prand• RAPIER is better than Prand when peers
have fewer topicsSimple model that hints on what is going on…
May 15, 2002 Stanford Networking Seminar
Experiments Data: used Client/Hostname matrix from proxy
logs as peer/item matrix. Each entry, in turn, is treated as a search item.– Similarly-structured “market basket” data– Has rare items (which current P2P networks don’t
support)– No universal model for market basket data– Can’t get a full index for many peers from current
P2P networks… and these networks don’t reflect well on rare items.
• Metric: ESS (Expected Search Size – number of peers probed till search is resolved). CDF of fraction of “searches” that have ESS below “x”.
May 15, 2002 Stanford Networking Seminar
ESS – Expected Search Size
• ESS: 1/(success probability in each probe) (when probes are “independent” – not true for GAS)
• Probe success probability:• Urand: fraction of peers that have the item in
their index• Prand: weight of each peer is its index size
divided by sum of index sizes of all peers.– Success prob: (weight of peers with item) /
(weight of peers without item)• RAPIER: the average, over possession rules peer
participates in, of fraction of peers in rule that have the item.
May 15, 2002 Stanford Networking Seminar
Peer-Item Matrix - Experiment
0 0 1 1 1 0 0 0 0 0
0 0 0 0 0 1 0 0 1 1
1 1 0 0 0 0 1 0 0 0
0 0 1 0 1 0 0 0 1 0
0 0 0 0 0 0 1 1 1 0
1 1 0 0 0 0 0 0 1 0
0 0 0 1 1 0 0 1 1 1
0 0 1 1 0 0 0 0 1 0
1 1 0 0 0 1 0 0 0 0
0 1 0 0 1 0 0 0 1 0
Items
Peers
????
??
??
May 15, 2002 Stanford Networking Seminar
Urand and Prand
0 0 1 1 1 0 0 0 0 0
0 0 0 0 0 1 0 0 1 1
1 1 0 0 0 0 1 0 0 0
0 0 1 0 1 0 0 0 1 0
0 0 0 0 0 0 1 1 1 0
1 1 0 0 0 0 0 0 1 0
0 0 0 1 1 0 0 1 1 1
0 0 1 1 0 0 0 0 1 0
1 1 0 0 0 1 0 0 0 0
0 1 0 0 1 0 0 0 1 0
ItemsPeers
?
Urand Ps=3/9 ESS=3
1/9
1/9
1/9
1/9
1/9
1/9
1/9
1/9
1/9
Prand ESS=29/9
3/29
3/29
3/29
3/29
3/29
3/29
3/29
3/29
5/29
May 15, 2002 Stanford Networking Seminar
RAPIER (Random Possession Rule)
0 0 1 1 1 0 0 0 0 0
0 0 0 0 0 1 0 0 1 1
1 1 0 0 0 0 1 0 0 0
0 0 1 0 1 0 0 0 1 0
0 0 0 0 0 0 1 1 1 0
1 1 0 0 0 0 0 0 1 0
0 0 0 1 1 0 0 1 1 1
0 0 1 1 0 0 0 0 1 0
1 1 0 0 0 1 0 0 0 0
0 1 0 0 1 0 0 0 1 0
Items
Peers ?
rule rule
0.5
0.25
0.25
0.5 0.5
May 15, 2002 Stanford Networking Seminar
Caveat: comparing apples and oranges
• When searching by possession rules we have bias towards peers that participate in more rules/ have more items.
• But, with this bias, a strategy has better chance of finding what it is looking for! So…
• We show that the likelihood of being probed is proportional to number of rules you participate in.
• Prand “blind search” strategy has same bias. • Thus, it is “fair” to compare Prand search with
possession-rule based RAPIER
May 15, 2002 Stanford Networking Seminar
GAS …Refining RAPIERIdeas:• Some rules are better than others (e.g., possession
of a very popular item carries weaker information) • Unsuccessful search carries information: suppose
you lost something, you think you lost it at home. You search home going through various closets and drawers and don’t find it, then you may decide to go search the office, even if you have not completed an exhaustive search at home. What happened? The posterior distribution on the item’s location had changed as a result of the search.
GAS – Greedy Strategy
May 15, 2002 Stanford Networking Seminar
All ItemsUrand Blind search (Gnutella),Prand Gnutella modified, Rapier, GAS – our algorithms
May 15, 2002 Stanford Networking Seminar
Rare Items: present in 1% of peers
May 15, 2002 Stanford Networking Seminar
Rarer items: 0.1% of peers
May 15, 2002 Stanford Networking Seminar
Even Rarer Item: 0.01% of peers
May 15, 2002 Stanford Networking Seminar
GAS – Greedy Strategy• Idea: use the search strategy that would have
optimized your search on previous queries.• Caveat: this is NP-Complete• Can do: greedy approximation strategy: GAS GAS: • initialize the “query vector” to a uniform distribution
on previous selections.• Iterate the following:
– Apply the possession rule that maximizes success probability with respect to the query posterior
– update the query posterior.
Theorem: GAS is a constant factor approximation of the optimal strategy
May 15, 2002 Stanford Networking Seminar
Building GAS strategies• GAS:
– Take a sample of items currently in your index D,E,F,G.– “search” for these items in each possession rule you
participate A,B,C– obtain a matrix: fraction of peers with item x in rule(y)
ItemRule()
D E F G
rule(A) 0.03
* 0.2 *
rule(B) * 0.04
* 0.1
rule(C) 0.1 0.2 0.03
*
May 15, 2002 Stanford Networking Seminar
GAS strategy (example) ItemRule()
D E F G
rule(A) 0.03
* 0.2 *
rule(B) * 0.04
* 0.1
rule(C) 0.1 0.2 0.03
*C,C,C,A,C,C,A,C,A,C,B,B,A,C,B,B,C,A,B,B,C
GAS search of size 21: 10 probes in rule(C) 6 probes in rule(B) 5 probes in rule(A)
RAPIER search of size 21: 7 probes in rule(C) 7 probes in rule(B) 7 probes in rule(A)
May 15, 2002 Stanford Networking Seminar
Summary• We proposed a general framework for associative
P2P search: exploit patterns inherent in human selections to boost search. Adapted to the P2P setting.
• Search strategies and the overlay structure are “symbiotic” and guided/boosted by previous selections/queries.
• “Common good” in par with “own welfare”: All data maintained by each peer has direct personal benefit (like gnutella). Helping others helps you…
• Possession rules:– Strategies are “approximations” to “standard”
similarity metrics… that work!!.– Easy to find other sources of desired item (for
alternative/parallel downloads)
May 15, 2002 Stanford Networking Seminar
Related work• IR-DM: association rules/collaborative filtering/Web search• P2P networks: unstructured networks; DHTs
– DHTs have “symbiotic” overlay/search strategy– Caching at peers (Freenet) adapt overlay according to search
• Intersection: – Crespo/Garcia-Molina 02– routing indexesSystem isolates “topics”+map queries/items to topics. Peer knows “summary” of what can be reached thru it/each neighborQuery keywords are used to select a neighbor who is a best matchDifferences from our approach:– No connection between search and overlay topology – Uses only text/keywords. We use co-location associations between
items.CG02: tradeoff between topic divergence (all nodes ending up with
similar index “summary”); or restricted coverage (number of peers included in each peer summary);
– neurogrid.net (Sam Joseph, U. Tokyo) “agent” text-based approach
• Peers learn and remember content of other peers
May 15, 2002 Stanford Networking Seminar
Future…• Integrate text matching (of query keywords) in
search strategy (use rule(O) if query keywords match O’s metadata)
• Select which possession rules to participate in (e.g., using item popularity heuristic or GAS-like selection)
• Search strategy gives more weight to more recent selections (are more indicative of next query)
• Explore other types of propagation rules • P2P “communities” ?• Integrate “Recommendation Systems” in P2P ?• Implementation …
May 15, 2002 Stanford Networking Seminar
May 15, 2002 Stanford Networking Seminar
Some Extra Comments…
• Issues with straightforward importing of IR techniques – Vector space approach– Similarity metrics
• Why we need to use several propagation rules in a search? (when searching according to “examples” in the index)
May 15, 2002 Stanford Networking Seminar
“Straight” IR vector-space approach
• #neighbors=O(dimension) - want small dimension• Yet, Matrix operations, e.g principal component
analysis (LSI), are hard in our distributed setting• Yet, each peer should be able to compute the
mapping for its queries and/or index • Proximity metric alone is insufficient (Need
different propagation rules)
• Peers are mapped to vectors, according to their index content. Queries are mapped to the vectors in the same space.
• Overlay topology is correlated with distances in this vector space (bias towards closer peers)
• Search propagation targets regions of the space that are “closest” to the query.
May 15, 2002 Stanford Networking Seminar
Why we need several propagation rules for the same
query –”decision-tree like” search
propagation rule =approx interest areaEach peer covers several interest areas, peers
have different sets of interest areas.Peer Query: 80% basketball 20%polo“World” Index: 5% basketball 0.1% poloAll “basketball” lovers would be close matches;
but need to direct search to more “polo” lovers multi-rule search strategy: “basketball” 200
peers; “polo” 200 peers