Self-stabilizing and Self-organizing Distributed Algorithms (Extended Abstract)

Self-stabilization ensures automatic recovery from an arbitrary state; we define self-organization as a property of algorithms which display local at- tributes. More precisely, we say that an algorithm is self-organizing if (1) it con- verges in sublinear time and (2) reacts "fast" to topology changes. If s(n) is an upper bound on the convergence time and d(n) is an upper bound on the convergence time following a topology change, then s(n) ∈ o(n) and d(n) ∈ o(s(n)). The self-organization property can then be used for gaining, in sub- linear time, global properties and reaction to changes. We present self-stabilizing and self-organizing algorithms for many distributed algorithms, including dis- tributed snapshot and leader election. We present a new randomized self-stabilizing distributed algorithm for cluster definition in communication graphs of bounded degree processors. These graphs reflect sensor networks deployment. The algorithm converges in O(logn) ex- pected number of rounds, handles dynamic changes locally and is, therefore, self- organizing. Applying the clustering algorithm to specific classes of communica- tion graphs, in O(logn) levels, using an overlay network abstraction, results in a self-stabilizing and self-organizing distributed algorithm for hierarchy definition. Given the obtained hierarchy definition, we present an algorithm for hierarchi- cal distributed snapshot. The algorithms are based on a new basic snap-stabilizing snapshot algorithm, designed for message passing systems in which a distributed spanning tree is defined and in which processors communicate using bounded links capacity. The combination of the self-stabilizing and self-organizing dis- tributed hierarchy construction and the snapshot algorithm form an efficient self- stabilizer transformer. Given a distributed algorithm for a specific task, we are able to convert the algorithm into a self-stabilizing algorithm for the same task with an expected convergence time of O(log 2 n) rounds.

[1]  Nathan Linial,et al.  The geometry of graphs and some of its algorithmic applications , 1994, Proceedings 35th Annual Symposium on Foundations of Computer Science.

[2]  Shlomi Dolev,et al.  SuperStabilizing protocols for dynamic distributed systems , 1995, PODC '95.

[3]  Roger Wattenhofer,et al.  Efficient computation of maximal independent sets in unstructured multi-hop radio networks , 2004 .

[4]  Hongwei Zhang,et al.  GS3: scalable self-configuration and self-healing in wireless networks , 2002, PODC '02.

[5]  Leslie Lamport,et al.  Distributed snapshots: determining global states of distributed systems , 1985, TOCS.

[6]  George Varghese,et al.  Self-stabilization by counter flushing , 1994, PODC '94.

[7]  Rajmohan Rajaraman,et al.  Accessing Nearby Copies of Replicated Objects in a Distributed Environment , 1999, Theory of Computing Systems.

[8]  Arobinda Gupta,et al.  Fault-containing self-stabilizing algorithms , 1996, PODC '96.

[9]  Yehuda Afek,et al.  Local Stabilizer , 2002, J. Parallel Distributed Comput..

[10]  Michael Luby A Simple Parallel Algorithm for the Maximal Independent Set Problem , 1986, SIAM J. Comput..

[11]  Leslie Lamport,et al.  Time, clocks, and the ordering of events in a distributed system , 1978, CACM.

[12]  Shlomi Dolev,et al.  Self Stabilization , 2004, J. Aerosp. Comput. Inf. Commun..

[13]  Shlomi Dolev,et al.  Optimal Time Self-Stabilization in Uniform Dynamic Systems , 1998, Parallel Process. Lett..

[14]  David Peleg,et al.  Bubbles: Adaptive Routing Scheme for High-Speed Dynamic Networks , 1999, SIAM J. Comput..

[15]  Shay Kutten,et al.  Tight fault locality , 1995, Proceedings of IEEE 36th Annual Foundations of Computer Science.

[16]  Shmuel Katz,et al.  Self-stabilizing extensions for message-passing systems , 1990, PODC '90.

[17]  Franck Petit,et al.  Enabling snap-stabilization , 2003, 23rd International Conference on Distributed Computing Systems, 2003. Proceedings..

[18]  Ajoy Kumar Datta,et al.  State-optimal snap-stabilizing PIF in tree networks , 1999, Proceedings 19th IEEE International Conference on Distributed Computing Systems.

[19]  Rajmohan Rajaraman,et al.  Accessing Nearby Copies of Replicated Objects in a Distributed Environment , 1997, SPAA '97.

[20]  Roger Wattenhofer,et al.  What cannot be computed locally! , 2004, PODC '04.

[21]  Helmut Prodinger,et al.  A result in order statistics related to probabilistic counting , 1993, Computing.

[22]  Boaz Patt-Shamir,et al.  Asynchronous and Fully Self-stabilizing Time-Adaptive Majority Consensus , 2005, OPODIS.

[23]  Felix C. Freiling,et al.  Time-Efficient Self-Stabilizing Algorithms through Hierarchical Structures , 2003, Self-Stabilizing Systems.

[24]  Edsger W. Dijkstra,et al.  Self-stabilizing systems in spite of distributed control , 1974, CACM.