Pure Prolog programs that distinguish between the equality and inequality of terms in a clean manner suffer from execution inefficiencies ; even when all terms of relevance are ground.
A recent example on SO is this answer. All answers and all failures are correct in this definition. Consider:
?- Es = [E1,E2], occurrences(E, Es, Fs). Es = Fs, Fs = [E, E], E1 = E2, E2 = E ; Es = [E, E2], E1 = E, Fs = [E], dif(E, E2) ; Es = [E1, E], E2 = E, Fs = [E], dif(E, E1) ; Es = [E1, E2], Fs = , dif(E, E1), dif(E, E2).
While the program is flawless from a declarative viewpoint, its direct execution on current systems like B, SICStus, SWI, YAP is unnecessarily inefficient. For the following goal, a choicepoint is left open for each element of the list.
?- occurrences(a,[a,a,a,a,a],M). M = [a, a, a, a, a] ; false.
This can be observed by using a sufficiently large list of
as as follows. You might need to adapt the
I such that the list can still be represented ; in SWI this would mean that
I must be small enough to prevent a resource error for the global stack like the following:
?- 24=I,N is 2^I,length(L,N), maplist(=(a),L). ERROR: Out of global stack
I must be large enough to provoke a resource error for the local stack:
?- 22=I,N is 2^I,length(L,N), maplist(=(a),L), ( Length=ok ; occurrences(a,L,M) ). I = 22, N = 4194304, L = [a, a, a, a, a, a, a, a, a|...], Length = ok ; ERROR: Out of local stack
To overcome this problem and still retain the nice declarative properties some comparison predicate is needed.
How should this comparison predicate be defined?
Here is such a possible definition:
equality_reified(X, X, true). equality_reified(X, Y, false) :- dif(X, Y).
Edit: Maybe the argument order should be reversed similar to the ISO built-in
compare/3 (link links to draft only).
An efficient implementation of it would handle the fast determinate cases first:
equality_reified(X, Y, R) :- X == Y, !, R = true. equality_reified(X, Y, R) :- ?=(X, Y), !, R = false. % syntactically different equality_reified(X, Y, R) :- X \= Y, !, R = false. % semantically different equality_reified(X, X, true). equality_reified(X, Y, false) :- dif(X, Y).
Edit: it is not clear to me whether or not
X \= Y is a suitable guard in the presence of constraints. Without constraints,
?=(X, Y) or
X \= Y are the same.
As suggested by @user1638891, here is an example how one might use such a primitive. The original code by mats was:
occurrences_mats(_, , ). occurrences_mats(X, [X|Ls], [X|Rest]) :- occurrences_mats(X, Ls, Rest). occurrences_mats(X, [L|Ls], Rest) :- dif(X, L), occurrences_mats(X, Ls, Rest).
Which can be rewritten to something like:
occurrences(_, , ). occurrences(E, [X|Xs], Ys0) :- reified_equality(Bool, E, X), ( Bool == true -> Ys0 = [X|Ys] ; Ys0 = Ys ), % ( Bool = true, Ys0 = [X|Ys] ; Bool = true, Ys0 = Ys ), occurrences(E, Xs, Ys). reified_equality(R, X, Y) :- X == Y, !, R = true. reified_equality(R, X, Y) :- ?=(X, Y), !, R = false. reified_equality(true, X, X). reified_equality(false, X, Y) :- dif(X, Y).
Please note that SWI's second-argument indexing is only activated, after you enter a query like
occurrences(_,,_). Also, SWI need the inherently nonmonotonic if-then-else, since it does not index on
(;)/2 – disjunction. SICStus does so, but has only first argument indexing. So it leaves one (1) choice-point open (at the end with