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Complete numbering

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In computability theory complete numberings are generalizations of Gödel numbering first introduced by A.I. Mal'tsev in 1963. They are studied because several important results like the Kleene's recursion theorem and Rice's theorem, which were originally proven for the Gödel-numbered set of computable functions, still hold for arbitrary sets with complete numberings.

Definition

A numbering ν {\displaystyle \nu } of a set A {\displaystyle A} is called complete (with respect to an element a A {\displaystyle a\in A} ) if for every partial computable function f {\displaystyle f} there exists a total computable function h {\displaystyle h} so that (Ershov 1999:482):

ν h ( i ) = { ν f ( i ) if   i dom ( f ) , a otherwise . {\displaystyle \nu \circ h(i)={\begin{cases}\nu \circ f(i)&{\mbox{if}}~i\in \operatorname {dom} (f),\\a&{\mbox{otherwise}}.\end{cases}}}

Ershov refers to the element a as a "special" element for the numbering. A numbering ν {\displaystyle \nu } is called precomplete if the weaker property holds:

ν f ( i ) = ν h ( i ) i dom ( f ) . {\displaystyle \nu \circ f(i)=\nu \circ h(i)\qquad i\in \operatorname {dom} (f).}

Examples

References

  • Y.L. Ershov (1999), "Theory of numberings", Handbook of Computability Theory, E.R. Griffor (ed.), Elsevier, pp. 473–506. ISBN 978-0-444-89882-1
  • A.I. Mal'tsev, Sets with complete numberings. Algebra i Logika, 1963, vol. 2, no. 2, 4-29 (Russian)
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