*I asked this over at [math.stackexchange](http://math.stackexchange.com/questions/873489), and though a number of people were interested enough to vote up the question, I didn't get an answer -- which makes me wonder whether it isn't quite so trivial/dumb as I originally feared it was. So let me try again in this more turbo-charged forum ...*

Take our old friend Robinson Arithmetic, and cut it down to a theory of successor and addition. 

To spell that out (just to ensure that we are singing from the same hymn sheet), take the first-order theory  with $\mathsf{0}$ as the sole constant, and $\mathsf{S}$ and $+$ as the built-in function signs, with the five axioms 

 1. $\mathsf{\forall x\ x \neq Sx}$
 2. $\mathsf{\forall x\forall y\ Sx = Sy \to x = y}$
 3. $\mathsf{\forall x(x \neq 0 \to \exists y\ x = Sy)}$
 4. $\mathsf{\forall x\ (x + 0) = x}$
 5. $\mathsf{\forall x\forall y\ (x + Sy) = S(x + y)}$

and whose deductive system is your favourite classical first-order logic with identity.

Since this cut-down theory doesn't represent the recursive functions, you can't use the usual proof of undecidability for an arithmetic. Since this cut-down theory doesn't even know that addition is commutative, you can't do the kind of manipulations inside the theory involved in a quantifier-elimination proof of decidability (cf. what happens when we add induction to this theory to get Presburger arithmetic, i.e. Peano Arithmetic minus multiplication). 

Ermmmm .... so .... Drat it, I *ought* to know how to prove that this cut-down theory is decidable or that it is undecidable. But I seem to have forgotten, assuming I ever knew, and searching around hasn't helped me out. OK folks, I'm more than likely to be having a senior moment here [*well, given the lack of answers on math.se maybe a forgivable senior moment?*] -- so be gentle! -- but how do we show the theory is (un)decidable? [*My bet is on undecidable, for what little  that it is worth ...*]