Narrowing power vs efficiency in synchronous set agreement: Relationship, algorithms and lower bound

The k -set agreement problem is a generalization of the uniform consensus problem: each process proposes a value, and each non-faulty process has to decide a value such that a decided value is a proposed value, and at most k different values are decided. It has been shown that any algorithm that sol...

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Vydáno v:Theoretical computer science Ročník 411; číslo 1; s. 58 - 69
Hlavní autoři: Mostéfaoui, Achour, Raynal, Michel, Travers, Corentin
Médium: Journal Article
Jazyk:angličtina
Vydáno: Oxford Elsevier B.V 2010
Elsevier
Témata:
[formula omitted]-resilience
Algorithmics. Computability. Computer arithmetics
Applied sciences
Artificial intelligence
Computer Science
Computer science; control theory; systems
Consensus
Distributed, Parallel, and Cluster Computing
Efficiency
Exact sciences and technology
Logic and foundations
Lower bound
Mathematical logic, foundations, set theory
Mathematics
Miscellaneous
Problem solving, game playing
Recursion theory
Round-based algorithm
Sciences and techniques of general use
Set agreement
Synchronous system
Theoretical computing
Lower bound
t -resilience
Synchronous system
Efficiency
Round-based algorithm
Set agreement
Consensus
Asynchronous
Computer theory
Solving
Algorithm
Failures
Computability
t-resilience
Proof
Problem solving
Environment
Failure
Power
t-Resilience
ISSN:0304-3975, 1879-2294
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Shrnutí:The k -set agreement problem is a generalization of the uniform consensus problem: each process proposes a value, and each non-faulty process has to decide a value such that a decided value is a proposed value, and at most k different values are decided. It has been shown that any algorithm that solves the k -set agreement problem in synchronous systems that can suffer up to t crash failures requires ⌊ t k ⌋ + 1 rounds in the worst case. It has also been shown that it is possible to design early deciding algorithms where no process decides and halts after min ( ⌊ f k ⌋ + 2 , ⌊ t k ⌋ + 1 ) rounds, where f is the number of actual crashes in a run ( 0 ≤ f ≤ t ). This paper explores a new direction to solve the k -set agreement problem in a synchronous system. It considers that the system is enriched with base objects (denoted has [ m , ℓ ] _SA objects) that allow solving the ℓ -set agreement problem in a set of m processes ( m < n ). The paper makes several contributions. It first proposes a synchronous k -set agreement algorithm that benefits from such underlying base objects. This algorithm requires O ( t ℓ m k ) rounds, more precisely, ⌊ t Δ ⌋ + 1 rounds, where Δ = m ⌊ k ℓ ⌋ + ( k  mod  ℓ ) . The paper then shows that this bound, that involves all the parameters that characterize both the problem ( k ) and its environment ( t , m and ℓ ), is a lower bound. The proof of this lower bound sheds additional light on the deep connection between synchronous efficiency and asynchronous computability. Finally, the paper extends its investigation to the early deciding case. It presents a k -set agreement algorithm that directs the processes to decide and stop by round min ( ⌊ f Δ ⌋ + 2 , ⌊ t Δ ⌋ + 1 ) . These bounds generalize the bounds previously established for solving the k -set agreement problem in pure synchronous systems.
Bibliografie:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0304-3975
1879-2294
DOI:10.1016/j.tcs.2009.09.002