EDIT: a better solution based on CapelliCs suggestion (this uses the
isodd predicate from below):
% if N0 and N2 are odd, cut, add N1 to the result and recurse
ff([N0,N1,N2|T], [N1|R]) :- isodd(N0), isodd(N2), !, ff([N1,N2|T], R).
% for any other case where the list has at least three members, cut and recurse
ff([_,N1,N2|T], R) :- !, ff([N1,N2|T], R).
% this is reached if the list has less that three members - we're done
% append and prepend '1' to the list to deal with the edges, call ff.
find(L, R) :- append(L, , L1), ff([1|L], R).
My old solution which keept track of the two previous values with extra arguments:
% helper predicate that succeds for odd numbers.
isodd(N) :- mod(N, 2) =:= 1.
% find(+I, +N1, +N2, +R, -L)
% find/5 is the predicate doing the actual work.
% I is the input list, N1 and N2 are the numbers before the current one,
% R is the intermediate result list and L the result.
% we're done if the input list is empty
find(, _, _, R, R) :- !.
% check if N0 and N2 are odd to see if N1 should be appended to the list.
% if yes, do a cut, append N1 to the result and recurse.
find([N0|T], N1, N2, R, L) :-
isodd(N0), isodd(N2), !,
append(R, [N1], R1), find(T, N0, N1, R1, L).
% if N0 and N2 are not odd (and thus the cut in the previous clause isn't
% reached) just continue the recursion.
find([N0|T], N1, _, R, L) :- find(T, N0, N1, R, L).
% find(+I, -L)
% this predicate is the entry point - initialize the result list and the first
% values for N1 and N2, and append 1 to the input list so we don't need an extra
% predicate for dealing with the last item.
find(I, L) :- append(I, , I1), find(I1, 1, 0, , L).