Let's divide the problem in three parts: the issues concerning **instantiation of variables** and the **accumulator pattern** which I use in a variation of that example:

```
add(0,Y,Y).
add(s(X),Y,Z):-add(X,s(Y),Z).
```

and a comment about your example that uses **composition of substitutions**.

What Prolog applies in order to see which rule (ie Horn clause) matches (whose head unifies) is the Unification Algorithm which tells, in particular, that if I have a variable, let's say, X and a funtor, ie, f(Y) those two term *unify* (there is a small part about the occurs check to...check but nevermind atm) hence there is a substitution that can let you convert one into another.

When your second rule is called, indeed R gets unified to s(Z). Do not be scared by the internal representation that Prolog gives to new, uninstantiated variables, it is simply a variable name (since it starts with '_') that stands for a code (Prolog must have a way to express constantly newly generated variables and so _G648, _G649, _G650 and so on).
When you call a Prolog procedure, the parameters you pass that are uninstantiated (R in this case) are used to contain the result of the procedure as it completes its execution, and it will contain the result since at some point during the procedure call it will be instantied to something (always through unification).
If at some point you have that a var, ie K is istantiated to s(H) (or s(_G567) if you prefer), it is still partilally instantiated and to have your complete output you need to recursively instantiate H.
To see what it will be instantiated to, have a read at the accumulator pattern paragraph and the sequent one, tho ways to deal with the problem.

The **accumulator pattern** is taken from functional programming and, in short, is a way to have a variable, the *accumulator* (in my case Y itself), that has the burden to carry the partial computations between some procedure calls. The pattern relies on recursion and has roughly this form:

- The base step of the recursion (my first rule ie) says always that since you have reached the end of the computation you can copy the partial result (now total) from your accumulator variable to your output variable (this is the step in which, through unification your output var gets instantiated!)
- The recursive step tells how to create a partial result and how to store it in the accumulator variable (in my case i 'increment' Y). Note that in the recursive step the output variable is never changed.

Finally, concerning your exemple, it follows another pattern, the **composition of substitutions** which I think you can understand better having thought about accumulator and instantiation via unification.

- Its base step is the same as the accumulator pattern but Y never changes in the recursive step while Z does
- It uses to unify the variable in Z with Y by partially instantiating all the computation
*at the end of each recursive call* after you've reached the base step and each procedure call is ending. So at the end of the first call the inner free var in Z has been substituted by unification many times by the value in Y.
Note the code below, after you have reached the bottom call, the procedure call stack starts to pop and your partial vars (S1, S2, S3 for semplicity) gets unified until R gets fully instantiated

Here is the stack trace:

```
add(s(s(s(0))),s(0),S1). ^ S1=s(S2)=s(s(s(s(0))))
add( s(s(0)) ,s(0),S2). | S2=s(S3)=s(s(s(0)))
add( s(0) ,s(0),S3). | S3=s(S4)=s(s(0))
add( 0 ,s(0),S4). | S4=s(0)
add( 0 ,s(0),s(0)). ______|
```