Partial function: Difference between revisions

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In [[mathematics]] and [[theoretical computer science]], a '''partial function''' on a set is a function whose [[domain of a function|domain]] of definition need not be the whole set.
In [[mathematics]] and [[theoretical computer science]], a '''partial function''' on a set is a function whose [[domain of a function|domain]] of definition need not be the whole set.


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==References==
==References==
* {{cite book | author=Zohar Manna | title=Mathematical Theory of Computation | publisher=McGraw-Hill | year=1974 | isbn=0-07-039910-7 | pages=44 }}
* {{cite book | author=Zohar Manna | title=Mathematical Theory of Computation | publisher=McGraw-Hill | year=1974 | isbn=0-07-039910-7 | pages=44 }}
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In mathematics and theoretical computer science, a partial function on a set is a function whose domain of definition need not be the whole set.

We may define a partial function f from X to Y by extending the codomain Y to Y* by an element ω for "undefined", assumed not to be in Y, so that f is a function in the usual sense from X to Y*, and we regard the domain of definition of f as the subset of X on which f does not take the value ω.

A function on X is total if its domain of definition is the whole of f: that is, if f is a function on X in the usual sense.

The set of partial functions from X to Y is partial order by extension: we say that f extends g if the domain of definition of f contains that of g and f agrees with g on the domain of g.

References

  • Zohar Manna (1974). Mathematical Theory of Computation. McGraw-Hill, 44. ISBN 0-07-039910-7.