TY - GEN
T1 - Brief announcement
T2 - 36th ACM Symposium on Principles of Distributed Computing, PODC 2017
AU - Dolev, Danny
AU - Erdmann, Michael
AU - Lutz, Neil
AU - Schapira, Michael
AU - Zair, Adva
N1 - Publisher Copyright: © 2017 Association for Computing Machinery.
PY - 2017/7/26
Y1 - 2017/7/26
N2 - We present and explore a model of stateless and self-stabilizing distributed computation, inspired by real-world applications such as routing on today's Internet. Processors in our model do not have an internal state, but rather interact by repeatedly mapping incoming messages ("labels") to outgoing messages and output values. While seemingly too restrictive to be of interest, stateless computation encompasses both classical game-theoretic notions of strategic interaction and a broad range of practical applications (e.g., Internet protocols, circuits, diffusion of technologies in social networks). Our main technical contribution is a general impossibility result for stateless self-stabilization in our model, showing that even modest asynchrony (with wait times that are linear in the number of processors) can prevent a stateless protocol from reaching a stable global configuration. Furthermore, we present hardness results for verifying stateless self-stabilization. We also address several aspects of the computational power of stateless protocols. Most significantly, we show that short messages (of length that is logarithmic in the number of processors) yield substantial computational power, even on very poorly connected topologies.
AB - We present and explore a model of stateless and self-stabilizing distributed computation, inspired by real-world applications such as routing on today's Internet. Processors in our model do not have an internal state, but rather interact by repeatedly mapping incoming messages ("labels") to outgoing messages and output values. While seemingly too restrictive to be of interest, stateless computation encompasses both classical game-theoretic notions of strategic interaction and a broad range of practical applications (e.g., Internet protocols, circuits, diffusion of technologies in social networks). Our main technical contribution is a general impossibility result for stateless self-stabilization in our model, showing that even modest asynchrony (with wait times that are linear in the number of processors) can prevent a stateless protocol from reaching a stable global configuration. Furthermore, we present hardness results for verifying stateless self-stabilization. We also address several aspects of the computational power of stateless protocols. Most significantly, we show that short messages (of length that is logarithmic in the number of processors) yield substantial computational power, even on very poorly connected topologies.
KW - Best-response dynamics
KW - Network protocols
KW - Self-stabilization
UR - http://www.scopus.com/inward/record.url?scp=85027888848&partnerID=8YFLogxK
U2 - 10.1145/3087801.3087854
DO - 10.1145/3087801.3087854
M3 - منشور من مؤتمر
T3 - Proceedings of the Annual ACM Symposium on Principles of Distributed Computing
SP - 419
EP - 421
BT - PODC 2017 - Proceedings of the ACM Symposium on Principles of Distributed Computing
Y2 - 25 July 2017 through 27 July 2017
ER -