Kishore Kothapalli Department of Computer Science Johns Hopkins University Baltimore...
Transcript of Kishore Kothapalli Department of Computer Science Johns Hopkins University Baltimore...
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Distributed Coloring in Bit Rounds
Kishore KothapalliDepartment of Computer Science
Johns Hopkins UniversityBaltimore, MD USA
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Vertex Coloring
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Proper coloring Not a Proper coloring
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Coloring a Cycle Graph
Cycle graph on n nodes Distributed algorithm: Every round, every uncolored
node chooses a color among R,G,B independently and uniformly at random. [Luby]
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Coloring a Cycle Graph
Cycle graph on n nodes Distributed algorithm: Every round, every uncolored
node chooses a color among R,G,B independently and uniformly at random.
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Coloring a Cycle Graph
Cycle graph on n nodes Algorithm: Every round, every uncolored node chooses a
color among R,G,B independently and uniformly at random.
Known: Every node gets colored in O(log n) rounds.4
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Coloring an Oriented Cycle Graph
Cycle graph on n nodes, with edges oriented. Edge u,v oriented u v, then u gets preference over v.
u v vu
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Coloring an Oriented Cycle Graph
Cycle graph on n nodes, with edges oriented. Algorithm: Nodes choose color ind. and u.a.r.
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Coloring an Oriented Cycle Graph
Cycle graph on n nodes, with edges oriented. Algorithm: Nodes choose color ind. and u.a.r.
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Coloring an Oriented Cycle Graph
Cycle graph on n nodes, with edges oriented. Algorithm: Nodes choose color ind. and u.a.r. Use orientation to break symmetry. Claim: Can color in O( ) rounds, w.h.p. !!
– Proof coming up...7
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Coloring an Oriented Cycle Graph
Consider situation after r = 4 rounds. Claim: Any arc P of length l = has at least one
colored node.– Pr[a given path P has no colored node after r rounds]
(1/2)lr 1/n4.
– Number of arcs of length l 2n.8
P:
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Coloring an Oriented Cycle Graph
Claim: Can finish in a further rounds.– Key: Orientation !!
Number of rounds = O( ), with high probability.
Round 1 Round 2 Round 3 Round l
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Questions
1)Can faster algorithms be designed for arbitrary oriented graphs?
2)How many bits have to be exchanged?
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Outline
Introduction Model Related Work Lower bounds Upper bound for constant degree graphs Upper bound for general graphs Experimental results Conclusion
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Introduction
Distributed system– Computation done by exchange of messages.– Graph G = (V,E) representing the topology.
Vertex coloring is a fundamental problem. Applications to
– Scheduling– Routing– Clustering
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Introduction
Distributed vertex coloring Number of colors
– Minimum required is called chromatic number, χ(G).– NPhard to compute χ(G). [GJ, 1979]– Hard to approximate χ(G) to any reasonable value.
Try to color with O(∆) or ∆+1 colors.
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Introduction
Deterministic algorithms– No polylogarithmic algorithms known.– Best known runs in O(n ) rounds [PS 1996].– Cannot be solved deterministically without unique
node identification numbers [BFFS, 2003].
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Introduction
Randomized algorithms– Decreases the number of rounds required
exponentially.– Known since more than a decade [Luby 1985].– O(log n) rounds to obtain a (∆+1)coloring.
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Outline
IntroductionModel Related Work Lower bounds Upper bound for constant degree graphs Upper bound for general graphs Experimental results Conclusion
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Model
Graph G = (V,E) modeling the topology of the distributed system.
Degree = ∆, |V| = n Edges have orientation.
– Bits can flow in both directions.
u v vu
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Model
lacyclic orientation: Minimum length of directed cycled induced by the orientation ≥l.
l = 4
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Model
Nodes do not need unique labels, know only n and ∆ Synchronized rounds Local computation is not counted.
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Model
Every bit round, every node can send (receive) at most 1 bit to (resp. from) its neighbors.– Bit complexity is the maximum number of bit rounds
required. One round of the algorithm contains several bit rounds.
vu1
vuvu1 0
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0Bit Round:
Round BR BR
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Model
How easy is it to provide orientation? Three scenarios:
1)Dynamic networks.2)Know a reference, such as distance to destination.3)Nodes are labeled distinctly.
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Outline
Introduction ModelRelated Work Lower bounds Upper bound for constant degree graphs Upper bound for general graphs Experimental results Conclusion
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Related Work Coloring
Luby [Luby, 1985] gave an O(log n) round algorithm to ∆+1 color a graph.
Special cases:– Cycle: O(log* n) rounds [CV 1986, GPS 1987], shown to
be optimal [Linial, 1992]– Rooted Trees: 6coloring in O(log* n) rounds [GPS, 1987]
Unlimited local computation– ∆ coloring in O(log*(n/∆)) rounds, [De Marco and Pelc,
2001] Many more...
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Related Work – Oriented Graphs
Sense of direction– Equivalent notion to that of orientation on edges.
Leader election with O(n) messages [Singh 87]. Spanning tree, depth first traversal [Flocchini, Mans,
Santoro 97].
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Outline
Introduction Model Related WorkLower bounds Upper bound for constant degree graphs Upper bound for general graphs Experimental results Conclusion
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Lower bound 1
(Unoriented) cycle graph on n nodes Any finite number of colors, any Las Vegas algorithm. Need Ω(log n) bit rounds, with high probability, to
arrive at a proper coloring.
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Lower bound 2
Cycle graph on n nodes, oriented in the same direction.
Any finite number of colors, any Las Vegas algorithm. Need Ω( ) bit rounds, with high probability, to
arrive at a proper coloring.26
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Outline
Introduction Model Related Work Lower boundsUpper bound for constant degree graphs Upper bound for general graphs Experimental results Conclusion
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Upper bound for constant degree oriented graphs
G = (V,E), ∆ = O(1) G is provided with a acyclic orientation. Algorithm:
– Uncolored nodes choose color independently and u.a.r. among 2∆ colors
– Conflicts resolved using orientation. Two phase analysis
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Upper Bound – constant degree graphs
Phase I Claim: After r = 4 rounds, every oriented path
P of length l = has at least one colored node, w.h.p.
Can be shown using union bound.– Number of paths of length l ≤ nl
P:
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Upper bound – constant degree graphs
Situation at the end of Phase I– Connected components of uncolored nodes– Diameter of any such component <
Phase II: Same algorithm
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Upper bound – constant degree graphs
Consider the following layering process– Layer 0 = u: no uncolored node u with u v – Remove nodes in layer 0.– Continue until no nodes are left.
0 41
2
1 2
3
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Upper bound – constant degree graphs
Claim: The layering process terminates in less than rounds
Phase II requires less than rounds.– Each round, at least one node gets colored.
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1 2
3
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Upper bound – constant degree graphs
Claim: label (v) for any node. Phase II requires less than rounds.
– Each round, at least one node gets colored.
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1 2
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Upper bound – constant degree graphs
Claim: label (v) for any node. Phase II requires less than rounds.
– Each round, at least one node gets colored. Nodes do not have to explicitly compute the labels.
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1 2
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Constant degree oriented graphs
Summary– Lower bound of Ω( ) on bit complexity.– Our algorithm achieves an upper bound of O( ).– Nodes need to know only their local degree.– With known techniques, can reduce number of colors
to ∆+1.– Simple algorithm. – Can arrive at local coloring: node u with degree du gets
a color between 1 and du+1.
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Outline
Introduction Model Related Work Lower bounds Upper bound for constant degree graphsUpper bound for general graphs Experimental results Conclusion
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Upper bound Arbitrary graphs
G = (V,E), degree = ∆. G is provided with a acyclic orientation Problems:
1) High degree graphs: Too many paths2) Low degree also poses a problem
Have to extend our algorithm and analysis. Goal: Arrive at a (1+ε)∆coloring with O( ) bits
for any constant ε > 0.
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Arbitrary Graphs
3phase algorithm– Phase I: Reduce degree to c.log n– Phase II: Break into connected components of
uncolored nodes with diameter less than – Phase III: Finish using orientation.
Bit rounds:– Phase I: O(log ∆ (log log n))– Phase II : – Phase III: O( )
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Arbitrary Graphs
Phase I Algorithm:
– Uncolored nodes choose a color between 1 and c'∆.– Conflicts resolved using orientation.
Using ideas from:– A particular ballsandbins game.
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Arbitrary Graphs
Phase II Reduced palette. Algorithm:
– Uncolored nodes choose a color between 1 and min 22c log n
– Conflicts resolved using orientation. Goal: Reduce degree of any node to Key Ideas:
– Orientation– Union bound
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Arbitrary Graphs
End of Phase II– Graph broken into connected components of
uncolored nodes.– Diameter of any connected component less than
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Arbitrary Graphs
Phase III: Key idea– Use a layering process as in Phase II of constant
degree oriented graphs.– Phase III takes less than rounds.
0 41
2
1 2
3
0
4
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Few Improvements
Can reduce complexity of Phase I to O(log ). Can reduce complexity of Phase II and Phase III
to O( ).
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Arbitrary oriented graphs
Summary:– Need acyclicity of the orientation– Bit complexity = O(log ∆) +
– For graphs with ∆ > 2 , best possible in general.– If every node has degree > log n, then can also arrive
at a local coloring.– With known techniques, can reduce the number of
colors to (1+ε)∆ for any constant ε > 0.
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Outline
Introduction Model Related Work Lower bounds Upper bound for constant degree graphs Upper bound for general graphsExperimental Results Conclusions
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Experimental results
Methodology– ANSI C implementation– SHA1 hash function used as random number generator– Multiple runs and average value.
Input: Oriented cycle graph49
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Experimental results
Cycle output picture
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8 10 12 14 16 18 200
1
2
3
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6
7
8
9
10
11LubyOriented
log(Size)
Roun
ds
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Conclusions
Orientation helps in symmetry breaking. Tight results. Further work:
– any ''good'' orientations?– any graph parameter?– In preparation: O(1)coloring trees and planar graphs.
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Acknowledgements
Joint work with:– Christian Scheideler, Johns Hopkins University
(presently at Technische Universität München, Germany).
– Melih Onus, Arizona State University– Christian Schindelhauer, University of Paderborn,
Germany. Preliminary results are to appear as ''Distributed
Coloring in bit rounds'', in Proc. of the IEEE Intl. Parallel and Distributed Processing Symposium (IPDPS), 2006.
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Thank You.