Divergence (computer science)

In computer science, a computation is said to diverge if it does not terminate or terminates in an exceptional state.^[1]^: 377 Otherwise it is said to converge. In domains where computations are expected to be infinite, such as process calculi, a computation is said to diverge if it fails to be productive (i.e. to continue producing an action within a finite amount of time).

Definitions

Various subfields of computer science use varying, but mathematically precise, definitions of what it means for a computation to converge or diverge.

Rewriting

In abstract rewriting, an abstract rewriting system is called convergent if it is both confluent and terminating.^[2]

The notation t ↓ n means that t reduces to normal form n in zero or more reductions, t↓ means t reduces to some normal form in zero or more reductions, and t↑ means t does not reduce to a normal form; the latter is impossible in a terminating rewriting system.

In the lambda calculus an expression is divergent if it has no normal form.^[3]

Denotational semantics

In denotational semantics an object function f : A → B can be modelled as a mathematical function $f:A\cup \{\perp \}\rightarrow B\cup \{\perp \}$ where ⊥ (bottom) indicates that the object function or its argument diverges.

Concurrency theory

In the calculus of communicating sequential processes (CSP), divergence occurs when a process performs an endless series of hidden actions.^[4] For example, consider the following process, defined by CSP notation: $Clock=tick\rightarrow Clock$ The traces of this process are defined as: $\operatorname {traces} (Clock)=\{\langle \rangle ,\langle tick\rangle ,\langle tick,tick\rangle ,\ldots \}=\{tick\}^{*}$ Now, consider the following process, which hides the tick event of the Clock process: $P=Clock\setminus tick$ As $P$ cannot do anything other than perform hidden actions forever, it is equivalent to the process that does nothing but diverge, denoted $\mathbf {div}$ . One semantic model of CSP is the failures-divergences models, which refines the stable failures model by distinguishes processes based on the sets of traces after which they can diverge.

Notes

^ C.A.R. Hoare (Oct 1969). "An Axiomatic Basis for Computer Programming" (PDF). Communications of the ACM. 12 (10): 576–583. doi:10.1145/363235.363259. S2CID 207726175.
^ Baader & Nipkow 1998, p. 9.
^ Pierce 2002, p. 65.
^ Roscoe, A.W. (2010). Understanding Concurrent Systems. Texts in Computer Science. doi:10.1007/978-1-84882-258-0. ISBN 978-1-84882-257-3.

References

Baader, Franz; Nipkow, Tobias (1998). Term Rewriting and All That. Cambridge University Press. ISBN 9780521779203.
Pierce, Benjamin C. (2002). Types and Programming Languages. MIT Press.
J. M. R. Martin and S. A. Jassim (1997). "How to Design Deadlock-Free Networks Using CSP and Verification Tools: A Tutorial Introduction" in Proceedings of the WoTUG-20.

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[1] C.A.R. Hoare (Oct 1969). "An Axiomatic Basis for Computer Programming" (PDF). Communications of the ACM. 12 (10): 576–583. doi:10.1145/363235.363259. S2CID 207726175.

[FOOTNOTEBaaderNipkow19989-2] Baader & Nipkow 1998, p. 9.

[FOOTNOTEPierce200265-3] Pierce 2002, p. 65.

[ucs-4] Roscoe, A.W. (2010). Understanding Concurrent Systems. Texts in Computer Science. doi:10.1007/978-1-84882-258-0. ISBN 978-1-84882-257-3.

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