I spent a week or two programming a simple logic solver. Having built it, I found myself wondering whether the language it solves is Turing-complete or not. So I coded up a small set of equations which accept any valid expression in the SKI combinator calculus, and produce a result set which contains the normal form of that expression. Since SKI *is* Turing-complete, proving that my language can execute SKI would demonstrate its Turing-completeness.

There is a glitch, however. The solver does not reduce the expression in normal order. Actually what it does is to try *every possible reduction order*. Which means that the solution set is typically *huge*. If a normal form exists, it will be in there *somewhere*, but it's difficult to tell *where*.

This brings me to two questions:

Is my language Turing-complete? Or do I need to find a better proof?

Is the number of solutions a computable function of the input?

(At first I assumed that the size of the solution set was exponential or factorial in the input size. But on closer inspection, this is not true. You can write huge expressions which are already in normal form, and tiny expressions which do not terminate. I have a feeling that determining the size of the solution set might be equivilent to solving the Halting Problem, but I'm not completely sure...)

first. So if a normal form exists, it will be at a finite position in the solution set. However, if a non-terminating reduction order exists, the soler is guaranteed to find it, and produce an infinite solution set. Is producing an infinite set whichcontainsthe right answersomewheresufficient for Turing-completeness? I mean, simply enumerating all possible SKI expressions would do that... – MathematicalOrchid Jun 4 '12 at 9:47