Your original version is much simpler to read. In particular, the recursive rule reads - reading it right-to-left
last_but_one(X, [_|T]) :- last_but_one(X, T).
^^^^^^^^^^
provided X is the lbo-element in T
^^ then, it follows, that (that's an arrow!)
^^^^^^^^^^^^^^^^^^^^^^
X is also the lbo-element of T with one more element
In other words: If you have already an lbo-element in a given list T
, then you can construct new lists with any further elements in front that also have the very same lbo-element.
One might debate which version is preferable as to efficiency. If you are really into that, rather take:
last_but_one_f1(E, Es) :-
Es = [_,_|Xs],
xs_es_lbo(Xs, Es, E).
xs_es_lbo([], [E|_], E).
xs_es_lbo([_|Xs], [_|Es], E) :-
xs_es_lbo(Xs, Es, E).
or even:
last_but_one_f2(E, [F,G|Es]) :-
es_f_g(Es, F, G, E).
es_f_g([], E, _, E).
es_f_g([G|Es], _, F, E) :-
es_f_g(Es, F, G, E).
Never forget general testing:
?- last_but_one(X, Es).
Es = [X,_A]
; Es = [_A,X,_B]
; Es = [_A,_B,X,_C]
; Es = [_A,_B,_C,X,_D]
; Es = [_A,_B,_C,_D,X,_E]
; Es = [_A,_B,_C,_D,_E,X,_F]
; false.
And here are some benchmarks on my olde labtop:
SICStus SWI
4.3.2 7.3.20-1
--------------+----------+--------
you 0.850s | 3.616s | 4.25×
they 0.900s | 16.481s | 18.31×
f1 0.160s | 1.625s | 10.16×
f2 0.090s | 1.449s | 16.10×
mat 0.880s | 4.390s | 4.99×
dcg 3.670s | 7.896s | 2.15×
dcgx 1.000s | 7.885s | 7.89×
ap 1.200s | 4.669s | 3.89×
The reason for the big difference is that both f1
and f2
run purely determinate without any creation of a choicepoint.
Using
bench_last :-
\+ ( length(Ls, 10000000),
member(M, [you,they,f1,f2,mat,dcg,dcgx,ap]), write(M), write(' '),
atom_concat(last_but_one_,M,P), \+ time(call(P,L,Ls))
).
last_but_one(X, [_,Y,Z|T]) :- last_but_ont(X, [Y,Z|T]).
which enforces that the 2nd argument be a list of at least 3 elements, making the constraints a little more precise. :)last_but_one(X, [X,_]).
So to have another clause that matches a two-element list as the second argument is redundant.