# Kleene's T predicate

In computability theory, the **T predicate**, first studied by mathematician Stephen Cole Kleene, is a particular set of triples of natural numbers that is used to represent computable functions within formal theories of arithmetic. Informally, the *T* predicate tells whether a particular computer program will halt when run with a particular input, and the corresponding *U* function is used to obtain the results of the computation if the program does halt. As with the s_{mn} theorem, the original notation used by Kleene has become standard terminology for the concept.[1]

## Definition

The definition depends on a suitable Gödel numbering that assigns natural numbers to computable functions. This numbering must be sufficiently effective that, given an index of a computable function and an input to the function, it is possible to effectively simulate the computation of the function on that input. The *T* predicate is obtained by formalizing this simulation.

The ternary relation *T*_{1}(*e*,*i*,*x*) takes three natural numbers as arguments. The triples of numbers (*e*,*i*,*x*) that belong to the relation (the ones for which *T*_{1}(*e*,*i*,*x*) is true) are defined to be exactly the triples in which *x* encodes a computation history of the computable function with index *e* when run with input *i*, and the program halts as the last step of this computation history. That is, *T*_{1} first asks whether *x* is the Gödel number of a finite sequence ⟨*x*_{j}⟩ of complete configurations of the Turing machine with index *e*, running a computation on input *i*. If so, *T*_{1} then asks if this sequence begins with the starting state of the computation and each successive element of the sequence corresponds to a single step of the Turing machine. If it does, *T*_{1} finally asks whether the sequence ⟨*x*_{j}⟩ ends with the machine in a halting state. If all three of these questions have a positive answer, then *T*_{1}(*e*,*i*,*x*) holds (is true). Otherwise, *T*_{1}(*e*,*i*,*x*) does not hold (is false).

There is a corresponding function *U* such that if *T*(*e*,*i*,*x*) holds then *U*(*x*) returns the output of the function with index *e* on input *i*.

Because Kleene's formalism attaches a number of inputs to each function, the predicate *T*_{1} can only be used for functions that take one input. There are additional predicates for functions with multiple inputs; the relation

- ,

holds if *x* encodes a halting computation of the function with index *e* on the inputs *i*_{1},...,*i*_{k}.

## Normal form theorem

The *T* predicate can be used to obtain **Kleene's normal form theorem** for computable functions (Soare 1987, p. 15; Kleene 1943, p. 52—53). This states there exists a primitive recursive function *U* such that a function *f* of one integer argument is computable if and only if there is a number *e* such that for all *n* one has

- ,

where *μ* is the *μ* operator ( is the smallest natural number for which holds) and holds if both sides are undefined or if both are defined and they are equal. Here *U* is a universal operation (it is independent of the computable function *f*) whose purpose is to extract, from the number *x* (encoding a complete computation history) returned by the operator *μ*, just the value *f*(*n*) that was found at the end of the computation.

## Formalization

The *T* predicate is primitive recursive in the sense that there is a primitive recursive function that, given inputs for the predicate, correctly determine the truth value of the predicate on those inputs. Similarly, the *U* function is primitive recursive.

Because of this, any theory of arithmetic that is able to represent every primitive recursive function is able to represent *T* and *U*. Examples of such arithmetical theories include Robinson arithmetic and stronger theories such as Peano arithmetic.

## Arithmetical hierarchy

In addition to encoding computability, the *T* predicate can be used to generate complete sets in the arithmetical hierarchy. In particular, the set

which is of the same Turing degree as the halting problem, is a complete unary relation (Soare 1987, pp. 28, 41). More generally, the set

is a complete (*n*+1)-ary predicate. Thus, once a representation of the *T* predicate is obtained in a theory of arithmetic, a representation of a -complete predicate can be obtained from it.

This construction can be extended higher in the arithmetical hierarchy, as in Post's theorem (compare Hinman 2005, p. 397). For example, if a set is complete then the set

is complete.

## Notes

- The predicate described here was presented in (Kleene 1943) and (Kleene 1952), and this is what is usually called "Kleene's
*T*predicate". (Kleene 1967) uses the letter*T*to describe a different predicate related to computable functions, but which cannot be used to obtain Kleene's normal form theorem.

## References

- Peter Hinman, 2005,
*Fundamentals of Mathematical Logic*, A K Peters. ISBN 978-1-56881-262-5 - Stephen Cole Kleene (Jan 1943). "Recursive predicates and quantifiers" (PDF).
*Transactions of the American Mathematical Society*.**53**(1): 41–73. doi:10.1090/S0002-9947-1943-0007371-8. Reprinted in*The Undecidable*, Martin Davis, ed., 1965, pp. 255–287. - —, 1952,
*Introduction to Metamathematics*, North-Holland. Reprinted by Ishi press, 2009, ISBN 0-923891-57-9. - —, 1967.
*Mathematical Logic,*John Wiley. Reprinted by Dover, 2001, ISBN 0-486-42533-9. - Robert I. Soare, 1987,
*Recursively enumerable sets and degrees,*Perspectives in Mathematical Logic, Springer. ISBN 0-387-15299-7