Many-one reduction

In computability theory and computational complexity theory, a many-one reduction (also called mapping reduction[1]) is a reduction which converts instances of one decision problem (whether an instance is in ) to another decision problem (whether an instance is in ) using an effective function. The reduced instance is in the language if and only if the initial instance is in its language . Thus if we can decide whether instances are in the language , we can decide whether instances are in its language by applying the reduction and solving . Thus, reductions can be used to measure the relative computational difficulty of two problems. It is said that reduces to if, in layman's terms is harder to solve than . That is to say, any algorithm that solves can also be used as part of a (otherwise relatively simple) program that solves .

Many-one reductions are a special case and stronger form of Turing reductions.[1] With many-one reductions, the oracle (that is, our solution for B) can be invoked only once at the end, and the answer cannot be modified. This means that if we want to show that problem A can be reduced to problem B, we can use our solution for B only once in our solution for A, unlike in Turing reduction, where we can use our solution for B as many times as needed while solving A.

This means that many-one reductions map instances of one problem to instances of another, while Turing reductions compute the solution to one problem, assuming the other problem is easy to solve. The many-one reduction is more effective at separating problems into distinct complexity classes. However, the increased restrictions on many-one reductions make them more difficult to find.

Many-one reductions were first used by Emil Post in a paper published in 1944.[2] Later Norman Shapiro used the same concept in 1956 under the name strong reducibility.[3]

Definitions

Formal languages

Suppose and are formal languages over the alphabets and , respectively. A many-one reduction from to is a total computable function that has the property that each word is in if and only if is in .

If such a function exists, one says that is many-one reducible or m-reducible to and writes

Subsets of natural numbers

Given two sets one says is many-one reducible to and writes

if there exists a total computable function with iff .

If the many-one reduction is injective, one speaks of a one-one reduction and writes .

If the many-one reduction is surjective, one says is recursively isomorphic to and writes[4]p.324

Many-one equivalence

If both and , one says is many-one equivalent or m-equivalent to and writes

Many-one completeness (m-completeness)

A set is called many-one complete, or simply m-complete, iff is recursively enumerable and every recursively enumerable set is m-reducible to .

Degrees

The relation indeed is an equivalence, its equivalence classes are called m-degrees and form a poset with the order induced by .[4]p.257

Some properties of the m-degrees, some of which differ from analogous properties of Turing degrees:[4]pp.555--581

  • There is a well-defined jump operator on the m-degrees.
  • The only m-degree with jump 0m is 0m.
  • There are m-degrees where there does not exist where .
  • Every countable linear order with a least element embeds into .
  • The first order theory of is isomorphic to the theory of second-order arithmetic.

There is a characterization of as the unique poset satisfying several explicit properties of its ideals, a similar characterization has eluded the Turing degrees.[4]pp.574--575

Myhill's isomorphism theorem can be stated as follows: "For all sets of natural numbers, ." As a corollary, and have the same equivalence classes.[4]p.325 The equivalences classes of are called the 1-degrees.

Many-one reductions with resource limitations

Many-one reductions are often subjected to resource restrictions, for example that the reduction function is computable in polynomial time, logarithmic space, by or circuits, or polylogarithmic projections where each subsequent reduction notion is weaker than the prior; see polynomial-time reduction and log-space reduction for details.

Given decision problems and and an algorithm N which solves instances of , we can use a many-one reduction from to to solve instances of in:

  • the time needed for N plus the time needed for the reduction
  • the maximum of the space needed for N and the space needed for the reduction

We say that a class C of languages (or a subset of the power set of the natural numbers) is closed under many-one reducibility if there exists no reduction from a language in C to a language outside C. If a class is closed under many-one reducibility, then many-one reduction can be used to show that a problem is in C by reducing a problem in C to it. Many-one reductions are valuable because most well-studied complexity classes are closed under some type of many-one reducibility, including P, NP, L, NL, co-NP, PSPACE, EXP, and many others. It is known for example that the first four listed are closed up to the very weak reduction notion of polylogarithmic time projections. These classes are not closed under arbitrary many-one reductions, however.

Many-one reductions extended

One may also ask about generalized cases of many-one reduction. One such example is e-reduction, where we consider that are recursively enumerable instead of restricting to recursive . The resulting reducibility relation is denoted , and its poset has been studied in a similar vein to that of the Turing degrees. For example, there is a jump set for e-degrees. The e-degrees do admit some properties differing from those of the poset of Turing degrees, e.g. an embedding of the diamond graph into the degrees below .[5]

Properties

  • The relations of many-one reducibility and 1-reducibility are transitive and reflexive and thus induce a preorder on the powerset of the natural numbers.
  • if and only if
  • A set is many-one reducible to the halting problem if and only if it is recursively enumerable. This says that with regards to many-one reducibility, the halting problem is the most complicated of all recursively enumerable problems. Thus the halting problem is r.e. complete. Note that it is not the only r.e. complete problem.
  • The specialized halting problem for an individual Turing machine T (i.e., the set of inputs for which T eventually halts) is many-one complete iff T is a universal Turing machine. Emil Post showed that there exist recursively enumerable sets that are neither decidable nor m-complete, and hence that there exist nonuniversal Turing machines whose individual halting problems are nevertheless undecidable.

Karp reductions

A polynomial-time many-one reduction from a problem A to a problem B (both of which are usually required to be decision problems) is a polynomial-time algorithm for transforming inputs to problem A into inputs to problem B, such that the transformed problem has the same output as the original problem. An instance x of problem A can be solved by applying this transformation to produce an instance y of problem B, giving y as the input to an algorithm for problem B, and returning its output. Polynomial-time many-one reductions may also be known as polynomial transformations or Karp reductions, named after Richard Karp. A reduction of this type is denoted by or .[6][7]

References

  1. Abrahamson, Karl R. (Spring 2016). "Mapping reductions". CSCI 6420 – Computability and Complexity. East Carolina University. Retrieved 2021-11-12.
  2. E. L. Post, "Recursively enumerable sets of positive integers and their decision problems", Bulletin of the American Mathematical Society 50 (1944) 284–316
  3. Norman Shapiro, "Degrees of Computability", Transactions of the American Mathematical Society 82, (1956) 281–299
  4. P. Odifreddi, Classical Recursion Theory: The theory of functions and sets of natural numbers (p.320). Studies in Logic and the Foundations of Mathematics, vol. 125 (1989), Elsevier 0-444-87295-7.
  5. S. Ahmad, Embedding the Diamond in the Enumeration Degrees (1991). Journal of Symbolic Logic, vol.56.
  6. Goldreich, Oded (2008), Computational Complexity: A Conceptual Perspective, Cambridge University Press, pp. 59–60, ISBN 9781139472746
  7. Kleinberg, Jon; Tardos, Éva (2006). Algorithm Design. Pearson Education. pp. 452–453. ISBN 978-0-321-37291-8.
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