Really nice question, +1!

Tail call (and, as a special case, tail *recursion*) optimization only applies if the predicate is *deterministic*! This is not the case here, so your predicate will always require the local stack space, no matter in which order you place the goals. The non-tail recursive version is more (time-)efficient here when generating all solutions because it needs to do fewer unifications on backtracking.

**EDIT**: I am expanding on this point since it is well worth studying the performance difference in more detail.

First, for clarity, I rename the two different versions to make clear which version I am talking about:

**Variant 1**: Non-tail recursive:

```
permute1([], []).
permute1([X|Rest], L) :-
permute1(Rest, L1),
select(X, L, L1).
```

**Variant 2**: Tail-recursive:

```
permute2([], []).
permute2(L, [P|P1]) :-
select(P, L, L1),
permute2(L1, P1).
```

Note again that, although the second version is clearly tail recursive, tail call (and hence also tail recursion) *optimisation* only helps if the predicate is *deterministic*, and hence cannot help when we generate all permutations, because choice points are still left in that case.

Note also that I am deliberately retaining the original variable naming and main predicate name to avoid introducing more variants. Personally, I prefer a naming convention that makes clear which variables denote *lists* by appending an **s** to their names, in analogy to regular English plural. Also, I prefer predicate names that more clearly exhibit the (at least intended and desirable) declarative, relational nature of the code, and recommend to avoid imperative names for this reason.

Consider now *unfolding* the first variant and partially evaluating it for a list of 3 elements. We start with a simple goal:

```
?- Xs = [A,B,C], permute1(Xs, L).
```

and then gradually unfold it by plugging in the definition of `permute1/2`

, while making all head unifications explicit. In the first iteration, we obtain:

?- Xs = [A,B,C], **Xs1 = [B,C]**, permute1(Xs1, L1), select(A, L, L1).

I am marking the head unifications in bold.

Now, still one goal of `permute1/2`

is left. So we repeat the process, again plugging in the predicate's only applicable rule body in place of its head:

?- Xs = [A,B,C], **Xs1 = [B,C], Xs2 = [C]**, permute1(Xs2, L2), select(B, L1, L2), select(A, L, L1).

One more pass of this, and we obtain:

?- Xs = [A,B,C], **Xs1 = [B,C], Xs2 = [C]**, select(C, L2, []), select(B, L1, L2), select(A, L, L1).

This is what the original goal looks like if we just unfold the definition of `permute1/2`

repeatedly.

Now, what about the second variant? Again, we start with a simple goal:

```
?- Xs = [A,B,C], permute2(Xs, Ys).
```

One iteration of unfolding `permute2/2`

yields the equivalent version:

?- Xs = [A,B,C], **Ys = [P|P1]**, select(P, Xs, L1), permute2(L1, P1).

and a second iteration yields:

?- Xs = [A,B,C], **Ys = [P|P1]**, select(P, Xs, L1), **Ys1 = [P1|P2]**, select(P1, L1, L2), permute2(L2, P2).

I leave the third and last iteration as a simple exercise that *I strongly recommend you do*.

And from this it is clear what we initially probably hadn't expected: A big difference lies in the *head unifications*, which the first version performs deterministically right at the start, and the second version performs **over and over on backtracking**.

This famous example nicely shows that, somewhat contrary to common expectation, tail recursion can be quite slow if the code is not deterministic.