# More compact definition

Given `word/1`,

``````word(W) :-
abs(ABs),
ABs = W.

abs([]).
abs([AB|ABs]) :-
abs(ABs),
ab(AB).

ab(a).
ab(b).

?- word(W).
W = []
;  W = [a]
;  W = [b]
;  W = [a,a]
;  W = [b,a]
;  W = [a,b]
;  W = [b,b]
;  W = [a,a,a]
;  W = [b,a,a]
;  W = [a,b,a]
;  W = [b,b,a]
;  W = [a,a,b]
;  W = [b,a,b]
;  W = [a,b,b]
;  W = [b,b,b]
;  W = [a,a,a,a]
;  ... .
``````

how does a more compact definition of `word/1` look like, otherwise identical w.r.t. termination and the set of solutions, fairness, with the following constraints:

1. No use of built-ins like `(=)/2`.

2. No use of control constructs like `(',')/2` or `(;)/2`, or `call/1`.

3. Uses one fact, one recursive rule, and one rule for `word/1`.

Maybe simpler is to ask for the terms `F1` ... `F4` in:

``````word(W) :-
p(F1).

p(F2).
p(F3) :-
p(F4).
``````

For the record: The property exploited here is closely related to the undecidability of termination of a single binary clause. Praise goes to:

Philippe Devienne, Patrick Lebègue, Jean-Christophe Routier, and Jörg Würtz. One binary horn clause is enough STACS '94.

• I expect the very same answers, not necessarily in exactly the same order, but at least the enumeration should be fair. Thus each solution will eventually be produced. Commented Feb 14, 2017 at 19:10
• @GuyCoder: The `ABs = W` just prevents that `word/1` has better termination properties. In fact, `word/1` terminates never. It finds solution, but ever terminates. Even for `word(non_word)` it just loops Commented Feb 14, 2017 at 19:53
• @GuyCoder: Exactly! The rule for `word/1` can only contain a single goal. Conjunction is not permitted (that's much too advanced :-) ). Commented Feb 14, 2017 at 19:56
• `abs`? Do you mean the arguments of the predicates? There are no restrictions. Not sure what you perceive as obviously stupid. Commented Feb 16, 2017 at 14:09
• @gniourf_gniourf: Usage of two built-ins `length/2`, and `maplist/2` usage of control constructs like conjunction and disjunction. And then these untypeable lambdas... Commented Feb 16, 2017 at 18:30

The solution I have come up with is:

```word(W) :-
p([[]|Ls], Ls, W).

p([W|_], _, W).
p([W0|Ws], [[a|W0],[b|W0]|Ls], W) :-
p(Ws, Ls, W).
```

```?- word(W).
W = [] ;
W = [a] ;
W = [b] ;
W = [a, a] ;
W = [b, a] ;
W = [a, b] ;
W = [b, b] ;
W = [a, a, a] ;
W = [b, a, a] ;
W = [a, b, a] ;
W = [b, b, a] ;
W = [a, a, b] ;
W = [b, a, b] ;
W = [a, b, b] ;
W = [b, b, b] ;
W = [a, a, a, a] ;
W = [b, a, a, a] ;
etc.
```

I am using a difference list to incrementally materialize the solutions I want the toplevel to report.

• I have clarified that this is a solution. Note that it should not be only correct, but also as elegant as possible, and so you may find for example better variable names.
– mat
Commented Feb 23, 2017 at 16:16
• Clearly you win. Nice job. Again thanks for posting what I was headed towards. I don't think I would have figured out `[[]|Ls]` in time. I was stuck on `[[]]`. I knew to use `p(..., W).` but didn't know exactly how. Commented Feb 23, 2017 at 16:27
• Somewhat I prefer `p([W|_], provisional_end, W).` to better clarify the role of this argument. Commented Feb 23, 2017 at 17:19
• @false you meant `Provisional_end`, I think. I prefer to call it `Production_point` when dealing (mentally) with the lazy queues (as this one is -- very nice!). `p` is a curious character - a cross between, or a sum of two predicates, `member( [E|T], _, E).` ; `member( [_|T], _, E):- member( T, _, E).` and `gen( [E|T], [[a|E], [b|E] | R], _) :- gen( T, R, _).` , thus reading and writing at it at the same time at 2 diffrt pts! Cudos to user:mat for the solution!! btw, 4 comparison, in Haskell it's `abs = [] : gen abs (drop 1 abs) where gen (x:t) p = (0:x):(1:x):gen t (drop 2 p)`. Commented Feb 23, 2017 at 18:07
• all of the above is clear in retrospect, of course. :) the `p` in Haskell isn't used but it does track the production point, which is maintained implicitly by Haskell; Prolog of course needs it explicit. /captain Hindsight signing off. Commented Feb 23, 2017 at 18:27

Okay so not an answer yet.

The closest I had was :

``````s_s1([],[a]).
s_s1([b|T],[a|T]).
s_s1([a|T],[b|T2]):-
s_s1(T,T2).

word([]).
word(W2):-
word(W),
s_s1(W,W2).
``````

Which does not either meet the criteria or give the right solutions!

So next I thought we could try and use prolog to find the answer.. The structure is given so we need to search for the args..

``````%First define the first 16 correct solutions..
correct_sols(X):-
X=[
[],
[a],
[b],
[a,a],
[b,a],
[a,b],
[b,b],
[a,a,a],
[b,a,a],
[a,b,a],
[b,b,a],
[a,a,b],
[b,a,b],
[a,b,b],
[b,b,b],
[a,a,a,a]
].

%Then a mi
provable(true, _) :- !.
provable((G1,G2), Defs) :- !,
provable(G1, Defs),
provable(G2, Defs).
provable(BI, _) :-
predicate_property(BI, built_in),
!,
call(BI).
provable(Goal, Defs) :-
member(Def, Defs),
copy_term(Def, Goal-Body),
provable(Body, Defs).

%From 4 Vars find 16 solutions to word(X)
vars_16sols(Vars,List):-
Vars =[Args,Args0,Args1,Argsx],
findnsols(16,X,provable(word(X),[
a(Args)-true,
a(Args0)-a(Args1),
word(X)-a(Argsx)]
),List).
%Evaluate the score, for the solutions found how many match correct
evaluate_score(Solutions,Score):-
correct_sols(C),
maplist(correct_test_tf,C,Solutions,TrueFalse),
findall(_,member(true,TrueFalse),Matches),
length(Matches,Score).

%The main search, give a form for the starting 4 arguments, if they
match all 16 correct stop.
startingargs_solution(Start,Sol):-
vars_16sols(Start,SolsStart),
evaluate_score(SolsStart,Score),
Score =16,
SolsStart=Sol.
%Othewise refine args, and try again.
startingargs_solution(Start,Sol):-
vars_16sols(Start,SolsStart),
evaluate_score(SolsStart,Score),
Score <16,
start_refined(Start,Refined),
startingargs_solution(Refined,Sol).
``````

We would still need to define :

1. correct_test_tf/3
2. start_refined/2 with some constraints, such as the size of the terms for args(needs to be reasonable to be a 'compact definition', and what things need to be included, i.e. at least `a` and `b` somewhere and probably `[]`.

Clearly not finished and not sure if it will be possible to do this but thought I would post an answer to see what people have to say.. The search is naive at the moment!

This is only testing the first 16 solutions but maybe that is adequate to get a correct answer..

Also maybe this is harder then solving the question on its own!

• Very interesting and worthwhile approach! It may be harder, but it is more general and flexible. I will give a separate 500 bounty for this answer if you manage to find a solution in this way. `call_with_inference_limit/3` may be useful for this.
– mat
Commented Feb 17, 2017 at 10:22
• Oh please, do a new question! Commented Feb 17, 2017 at 10:51

My closest yet.

``````unfold20([], []).
unfold20([H|T], [[a|H], [b|H]|L]) :-
unfold20(T, L).

member20(X, [X|_]).
member20(X, [_|Tail]) :-
member20(X, Tail).

swap20(R,R) :-
write('swap20 R: '),write(R),nl.

swap20(In,L) :-
write('swap20 In: '),write(In),nl,
unfold20(In,L),
swap20(L,_),
write('swap20 L: '),write(L),nl.

word20(W) :-
swap20([[]],L),
write('word20 L: '),write(L),nl,
member20(W,L),
write('word20 W: '),write(W),nl.
``````

``````?- word20(X).
swap20 R: [[]]
word20 L: [[]]
word20 W: []
X = [] ;
swap20 In: [[]]
swap20 R: [[a],[b]]
swap20 L: [[a],[b]]
word20 L: [[a],[b]]
word20 W: [a]
X = [a] ;
word20 W: [b]
X = [b] ;
swap20 In: [[a],[b]]
swap20 R: [[a,a],[b,a],[a,b],[b,b]]
swap20 L: [[a,a],[b,a],[a,b],[b,b]]
swap20 L: [[a],[b]]
word20 L: [[a],[b]]
word20 W: [a]
X = [a] ;
word20 W: [b]
X = [b] ;
swap20 In: [[a,a],[b,a],[a,b],[b,b]]
swap20 R: [[a,a,a],[b,a,a],[a,b,a],[b,b,a],[a,a,b],[b,a,b],[a,b,b],[b,b,b]]
swap20 L: [[a,a,a],[b,a,a],[a,b,a],[b,b,a],[a,a,b],[b,a,b],[a,b,b],[b,b,b]]
swap20 L: [[a,a],[b,a],[a,b],[b,b]]
swap20 L: [[a],[b]]
word20 L: [[a],[b]]
word20 W: [a]
X = [a] ;
word20 W: [b]
X = [b] ;
swap20 In: [[a,a,a],[b,a,a],[a,b,a],[b,b,a],[a,a,b],[b,a,b],[a,b,b],[b,b,b]]
swap20 R: [[a,a,a,a],[b,a,a,a],[a,b,a,a],[b,b,a,a],[a,a,b,a],[b,a,b,a],[a,b,b,a],[b,b,b,a],[a,a,a,b],[b,a,a,b],[a,b,a,b],[b,b,a,b],[a,a,b,b],[b,a,b,b],[a,b,b,b],[b,b,b,b]]
swap20 L: [[a,a,a,a],[b,a,a,a],[a,b,a,a],[b,b,a,a],[a,a,b,a],[b,a,b,a],[a,b,b,a],[b,b,b,a],[a,a,a,b],[b,a,a,b],[a,b,a,b],[b,b,a,b],[a,a,b,b],[b,a,b,b],[a,b,b,b],[b,b,b,b]]
swap20 L: [[a,a,a],[b,a,a],[a,b,a],[b,b,a],[a,a,b],[b,a,b],[a,b,b],[b,b,b]]
swap20 L: [[a,a],[b,a],[a,b],[b,b]]
swap20 L: [[a],[b]]
word20 L: [[a],[b]]
word20 W: [a]
X = [a]
``````

If you look you will see that there is no use of `;` which I am sure is a problem some people are having. Also all of the rules are simple enough that they should be able to be folded into the requirements by using additional arguments. e.g. `unfold(A,B)` would become `unfold(A,B,C,D)` or a variation.

The problem with this version is that I get the correct answers as the evaluation progresses, it is just getting them back to the top level.

e.g.

``````swap20 L: [[a,a,a],[b,a,a],[a,b,a],[b,b,a],[a,a,b],[b,a,b],[a,b,b],[b,b,b]]
swap20 L: [[a,a],[b,a],[a,b],[b,b]]
swap20 L: [[a],[b]]
``````

I will keep working on this before the dead line, but if someone is able to use what I have here, hats off to them, I just ask that you give credit if any part of this helped you get the answer.

The `unfold` predicate is based on this SO answer. Credit to salva

`member` is an old friend. Notice that it starts with `[[]]` and not `[]`.

`swap` I created this predicate. I have swap working for different variation yet the variation fails for a different reason.

## Debugger output of mat's answer

I looked at Mat's answer more closely with a debugger because it might hold the answer to a similar problem where I can generate the answers but not return them independently to Top.

Mat's answer copied here for reference.

``````p([W|_], _, W).

p([W0|Ws], [[a|W0],[b|W0]|Ls], W) :-
p(Ws, Ls, W).

word(W) :-
p([[]|Ls], Ls, W).
``````

The part of interest is far to the right as comments. I would suggest that you copy from here and past into a app that allows you to see all of the line without wrapping or hidden.

The column on the left was created with SWI-Prolog running the query with `trace` and the comments on the right were created by running the query with `gtrace` and hand copying the values and noting the level for indentation.

``````?- word(W).
Call: (8) word(_822) ? creep                                                                                                                                      % word(W) :-
Call: (9) p([[]|_1010], _1010, _822) ? creep                                                                                                                      %   p([[]|Ls], Ls, W).
Exit: (9) p([[]|_1010], _1010, []) ? creep                                                                                                                        %   p([W|_], _, W).                             % W = []
Exit: (8) word([]) ? creep                                                                                                                                        % p([[]|Ls], Ls, W).                            % W = []
W = [] ;
Redo: (9) p([[]|_1010], _1010, _822) ? creep                                                                                                                      %   p([W0|Ws], [[a|W0],[b|W0]|Ls], W) :-        %              W0 = []    Ws = [[a],[b]|Ls]
Call: (10) p([[a], [b]|_1028], _1028, _822) ? creep                                                                                                               %     p(Ws, Ls, W).                             %              W0 = []    Ws = [[a],[b]|Ls]
Exit: (10) p([[a], [b]|_1028], _1028, [a]) ? creep                                                                                                                %     p([W|_], _, W).                           % W = [a]
Exit: (9) p([[], [a], [b]|_1028], [[a], [b]|_1028], [a]) ? creep                                                                                                  %   p(Ws, Ls, W).                               % W = [a]      W0 = []    Ws = [[a],[b]|Ls]
Exit: (8) word([a]) ? creep                                                                                                                                       % p([[]|Ls], Ls, W).                            % W = [a]                                                                               Ls = [[a],[b]|_2312]
W = [a] ;
Redo: (10) p([[a], [b]|_1028], _1028, _822) ? creep                                                                                                               %     p([W0|Ws], [[a|W0],[b|W0]|Ls], W) :-      %              W0 = [a]   Ws = [    [b],[a,a],[b,a]|Ls]
Call: (11) p([[b], [a, a], [b, a]|_1052], _1052, _822) ? creep                                                                                                    %       p(Ws, Ls, W).                           %              W0 = [a]   Ws = [    [b],[a,a],[b,a]|Ls]
Exit: (11) p([[b], [a, a], [b, a]|_1052], _1052, [b]) ? creep                                                                                                     %       p([W|_], _, W).                         % W = [b]
Exit: (10) p([[a], [b], [a, a], [b, a]|_1052], [[a, a], [b, a]|_1052], [b]) ? creep                                                                               %     p(Ws, Ls, W).                             % W = [b]      W0 = [a]   Ws = [    [b],[a,a],[b,a]|Ls]
Exit: (9) p([[], [a], [b], [a, a], [b, a]|_1052], [[a], [b], [a, a], [b, a]|_1052], [b]) ? creep                                                                  %   p(Ws, Ls, W).                               % W = [b]      W0 = []    Ws = [[a],[b],[a,a],[b,a]|_2324]                              Ls = [        [a,a],[b,a]|_2324]
Exit: (8) word([b]) ? creep                                                                                                                                       % p([[]|Ls], Ls, W).                            % W = [b]                                                                               Ls = [[a],[b],[a,a],[b,a]|_2324]
W = [b] .
Redo: (11) p([[b], [a, a], [b, a]|_1052], _1052, _822) ? creep                                                                                                    %       p([W0|Ws], [[a|W0],[b|W0]|Ls], W) :-    %              W0 = [b]   Ws = [        [a,a],[b,a],[a,b],[b,b]|Ls]
Call: (12) p([[a, a], [b, a], [a, b], [b, b]|_1076], _1076, _822) ? creep                                                                                         %         p(Ws, Ls, W).                         %              W0 = [b]   Ws = [        [a,a],[b,a],[a,b],[b,b]|Ls]
Exit: (12) p([[a, a], [b, a], [a, b], [b, b]|_1076], _1076, [a, a]) ? creep                                                                                       %         p([W|_], _, W).                       % W = [a,a]
Exit: (11) p([[b], [a, a], [b, a], [a, b], [b, b]|_1076], [[a, b], [b, b]|_1076], [a, a]) ? creep                                                                 %       p(Ws, Ls, W).                           % W = [a,a]    W0 = [b]   Ws = [        [a,a],[b,a],[a,b],[b,b]|Ls]
Exit: (10) p([[a], [b], [a, a], [b, a], [a, b], [b, b]|_1076], [[a, a], [b, a], [a, b], [b, b]|_1076], [a, a]) ? creep                                            %     p(Ws, Ls, W).                             % W = [a,a]    W0 = [a]   Ws = [    [b],[a,a],[b,a],[a,b],[b,b]|_2348]                  Ls = [                    [a,b],[b,b]|_2348]
Exit: (9) p([[], [a], [b], [a, a], [b, a], [a, b], [b|...]|_1076], [[a], [b], [a, a], [b, a], [a, b], [b, b]|_1076], [a, a]) ? creep                              %   p(Ws, Ls, W).                               % W = [a,a]    W0 = []    Ws = [[a],[b],[a,a],[b,a],[a,b],[b,b]|_2348]                  Ls = [        [a,a],[b,a],[a,b],[b,b]|_2348]
Exit: (8) word([a, a]) ? creep                                                                                                                                    % p([[]|Ls], Ls, W).                            % W = [a,a]                                                                             Ls = [[a],[b],[a,a],[b,a],[a,b],[b,b]|_2348]
W = [a, a] ;
Redo: (12) p([[a, a], [b, a], [a, b], [b, b]|_1076], _1076, _822) ? creep
Call: (13) p([[b, a], [a, b], [b, b], [a, a, a], [b, a, a]|_1100], _1100, _822) ? creep                                                                           %         p([W0|Ws], [[a|W0],[b|W0]|Ls], W) :-  %              W0 = [a,a] Ws = [              [b,a],[a,b],[b,b],[a,a,a],[b,a,a]|Ls]
Exit: (13) p([[b, a], [a, b], [b, b], [a, a, a], [b, a, a]|_1100], _1100, [b, a]) ? creep                                                                         %           p(Ws, Ls, W).                       %              W0 = [a,a] Ws = [              [b,a],[a,b],[b,b],[a,a,a],[b,a,a]|Ls]
Exit: (12) p([[a, a], [b, a], [a, b], [b, b], [a, a, a], [b, a|...]|_1100], [[a, a, a], [b, a, a]|_1100], [b, a]) ? creep                                         %           p([W|_], _, W).                     % W = [b,a]
Exit: (11) p([[b], [a, a], [b, a], [a, b], [b, b], [a, a|...], [b|...]|_1100], [[a, b], [b, b], [a, a, a], [b, a, a]|_1100], [b, a]) ? creep                      %         p(Ws, Ls, W).                         % W = [b,a]    W0 = [a,a] Ws = [              [b,a],[a,b],[b,b],[a,a,a],[b,a,a]|Ls]
Exit: (10) p([[a], [b], [a, a], [b, a], [a, b], [b, b], [a|...], [...|...]|...], [[a, a], [b, a], [a, b], [b, b], [a, a, a], [b, a|...]|_1100], [b, a]) ? creep   %       p(Ws, Ls, W).                           % W = [b,a]    W0 = [b]   Ws = [        [a,a],[b,a],[a,b],[b,b],[a,a,a],[b,a,a]|_2372]  Ls = [                                [a,a,a],[b,a,a]|_2372]
Exit: (9) p([[], [a], [b], [a, a], [b, a], [a, b], [b|...], [...|...]|...], [[a], [b], [a, a], [b, a], [a, b], [b, b], [a|...], [...|...]|...], [b, a]) ? creep   %     p(Ws, Ls, W).                             % W = [b,a]    W0 = [a]   Ws = [    [b],[a,a],[b,a],[a,b],[b,b],[a,a,a],[b,a,a]|_2372]  Ls = [                    [a,b],[b,b],[a,a,a],[b,a,a]|_2372]
Exit: (8) word([b, a]) ? creep                                                                                                                                    %   p(Ws, Ls, W).                               % W = [b,a]    W0 = []    Ws = [[a],[b],[a,a],[b,a],[a,b],[b,b],[a,a,a],[b,a,a]|_2372]  Ls = [        [a,a],[b,a],[a,b],[b,b],[a,a,a],[b,a,a]|_2372]
W = [b, a] ;                                                                                                                                                         % p([[]|Ls], Ls, W).                            % W = [b,a]                                                                             Ls = [[a],[b],[a,a],[b,a],[a,b],[b,b],[a,a,a],[b,a,a]|_2372]
``````
• You may be able to use an additional argument to make the toplevel report the answer via a binding!
– mat
Commented Feb 23, 2017 at 15:22
• I really like the `unfold20`!!! But think of it: It will also have to give one element "back". Commented Feb 23, 2017 at 15:49
• (Just a general remark: There is really notreason to use write/1. The toplevel writes much better!) Commented Feb 23, 2017 at 15:52
• Just post your queries in such a matter that the toplevel produces the answers for you - no need for write (and if, then rather use `writeq/1`). Commented Feb 23, 2017 at 16:05
• Also: It's best to post solutions separately Commented Feb 23, 2017 at 16:47

Normally I would post these as a single answer, but @false asked me to keep them separate.

If you read my comments and answers you will see that I was aware that I had to pass the result from one iteration back into the next iteration. What gave me insight into that was using a cross-product predicate which I found in

"The Craft of Prolog" by Richard A. O'Keefe pg. 243

If you are serious about learning Prolog, the book is a must have.

To quote the Preface

There are a lot of introductory Prolog books around. This is not one of them. Think of it as "second steps in Prolog". If you have already read one of the introductory books, if you have taken an introductory course on Prolog, if you have written ore or two Prolog programs, and if you are wondering why it is still hard to write good Prolog programs, this book is meant to help you. The purpose of the book is to show you how you can write Prolog programs that work, that don't take an unreasonable amount of time, and that are clean enough to show to your friends.

Here is a slight variation that I used for one variation that did not work.

``````combine(X,Y,[X,Y]).

product(P,Xs,Ys,PXYs) :-
product1(Xs,Ys,PXYs,P).

product1([],_,[],_).

product1([X|Xs],Ys,PXYs0,P) :-
product1(Ys,X,P,PXYs0,PXYs1),
product1(Xs,Ys,PXYs1,P).

product1([],_,_) --> [].

product1([Y|Ys],X,P) -->
{
call(P,X,Y,PXY)
},
[PXY],
product1(Ys,X,P).

?- product(combine,[a,b],[a,b],R).
R = [[a, a], [a, b], [b, a], [b, b]].
``````

So to clarify, the intended solution is an instance of the following schema?

``````fact(Args).

recursive_rule(Args0) :-
recursive_rule(Args1).

word(W) :-
recursive_rule(Args).
``````

Where each occurrence of an `Args` variable stands for zero or more terms and presumably (but not necessarily) `fact` and `recursive_rule` are actually the same functor?

• Yes. Only when fact and recursive_rule are of the same predicate you have a chance to get what we want. The number of arguments is irrelevant since you can always represent arguments in a single argument with a corresponding function symbol. Commented Feb 16, 2017 at 16:48

With Guy coder's suggestions this is closer?

``````unfold([], []).
unfold([H|T], [[a|H], [b|H]|L]) :-
unfold(T, L).

ab([], [[]]).
ab([_|N1],L):-
ab(N1, L1),
unfold(L1, L).

word(X):-
length(List,_),
ab(List,Values),
member(X,Values).
``````

Not a solution, but an insight toward a solution.

This started with using DCG

``````abs4 --> [].
abs4 --> abs4, ([a] | [b]).
``````

``````?- phrase(abs4,X).
X = [] ;
X = [a] ;
X = [b] ;
X = [a, a] ;
X = [a, b] ;
X = [b, a] ;
X = [b, b] ;
X = [a, a, a] ;
X = [a, a, b] ;
X = [a, b, a] ;
X = [a, b, b] ;
X = [b, a, a] ;
X = [b, a, b] ;
X = [b, b, a] ;
X = [b, b, b] ;
X = [a, a, a, a] ;
X = [a, a, a, b] ;
``````

then looking at the listing

``````?- listing(abs4).
abs4(A, A).
abs4(A, C) :-
abs4(A, B),
(   B=[a|C]
;   B=[b|C]
).
``````

and using `member` to remove the `;`.

``````word5(W) :-
abs5(W,[]).
abs5(A, A).
abs5(A, C) :-
abs5(A, [D|C]),
member5(D,[a,b]).
member5(X, [X|_]).
member5(X, [_|Tail]) :-
member5(X, Tail).
``````

``````?- word5(X).
X = [] ;
X = [a] ;
X = [b] ;
X = [a, a] ;
X = [a, b] ;
X = [b, a] ;
X = [b, b] ;
X = [a, a, a] ;
X = [a, a, b] ;
X = [a, b, a] ;
X = [a, b, b] ;
X = [b, a, a]
``````
• too disjunctive, the original `unfold20` shows you that such local disjunction is not needed Commented Feb 23, 2017 at 16:54
• @false Thanks. I know that now, but this was variation `4` and `5`, I didn't discover the power of `unfold` for this question until later. I did find `unfold` in my initial research for parts that could be used, but until I started working with it, as you like to suggest, did I see that it was on the path to the correct solution. Since I have been doing functional programming for years, `F#` I knew how powerful `fold` and `unfold` are, but I just was not as adept as using them with Prolog. Need to work with them more, especially now that I have seen the solution. :) Commented Feb 23, 2017 at 17:30