# List exploration via backtracking & mutual recursion

I'm trying to implement an exploration algorithm using backtracking. The aim is to find what might be called 'chains' within words using two rules:

• if X is selected, then so are all other instances of X
• e.g. from `[a,b,b,a,b]` we need `[a,_,_,b,_]`
• if Y is selected, so is Y's 'opposite' - i.e. the one at the equi-distant from the end.
• e.g. with `[a,c,c,c,b]` we take `[a,_,_,_,b]`

and so together abyxzbzxxcb would first select ab...b...cb.

• a is chosen because it the head
• by rule 2 the last b is chosen
• by rule 1, the first b is chosen
• by rule 2, the c is chosen
• as there are no other c's, the code should reapply rule 1 to get the middle b, from which no further moves are possible.

My idea is to use mutual recursion with 2 predicates:

• `find_another`: that finds another element with the same letter;
• `find_palindrome`: that picks the element equi-distant from the end.

I'm testing this with `find_loop([a,b,y,x,z,b,z,x,x,c,b],Loop).` and am failing to pick up the middle `(5,b)`, and to stop after the first result. I think it is not correctly backtracking in `find_another` to keep looking for more `b`s, and I fear that even if it did, I would lose part of my Hist(ory) along the way.

Perhaps a better approach is to use a `findall` in `find_another`, and then pass each result to `find_palindrome`, but I thought I might be able to do everything via backtracking.

``````find_loop(Word, Loop) :-
zip(Word, 0, WZ),
length(Word, WL), Word_length is WL - 1,
[X|_] = WZ,
find_another(X, Word_length, WZ, [X], Loop).
/*
Get a element with same letter
if not in history, explore further via its palindrome
else search for existing element's palindrome
*/
find_another((N,L), Word_length, Word, Hist_in, Hist_out) :-
member((X,L), Word),
(
\+ member((X,L), Hist_in),
find_another((N_palindrome,X), Word_length, Word, [(N_palindrome,X)| Hist_in], Hist_out)
;
find_palindrome((N,L), Word_length, Word, Hist_in, Hist_out)
).

/*
Finds the palindrome element, and then looks for others with new letter
*/
find_palindrome((N,L), Word_length, Word, Hist_in, Hist_out) :-
N_palindrome is Word_length - N,
member((N_palindrome,X), Word),
(
\+ member((N_palindrome,X), Hist_in) ->
Hist_next = [(N_palindrome,X)| Hist_in],
find_another((N_palindrome,X), Word_length, Word, Hist_next, Hist_out)
;
Hist_out = Hist_in
).

%% [a,b,c,...] becomes [(0,a),(1,b),...]
zip([], _, []).
zip([H | T], C, [(C,H)|Z] ) :-
C1 is C + 1,
zip(T,C1,Z).
``````
• I might be a little daft, but I'm not sure what the stated rules mean. In the first, If an X is in the list, then so are all other Xs, what does "other Xs" really mean? Can you give an example? The second rule misuses the term "palindrome". A "palindrome" would be a list where, for every i-th element out of `N` elements, list[i] equals list[N-i-1] (if I use a C-ish notation). So the second rule sounds like it's defining a list which is a palindrome, but it's a little obscure. – lurker Oct 26 '14 at 11:22
• You are write about Palindrome but I hoped that it figuratively gave the idea of 'equi-distant from other end' – Simon H Oct 26 '14 at 11:32
• I think I understand the equidistant from the other end idea, but that seems then like rule 2 just defines an entire palindrome (i.e., if a list complies with rule 2, it's a palindrome). So I am still not sure I understand the rules. – lurker Oct 26 '14 at 11:47

``````find_another((_,L), Word_length, Word, Hist_in, Hist_out) :-