# Reification of term equality/inequality

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

1mo the 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

2do the 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.

## Example

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 []).

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This is indeed an interesting question. Could you add the code from the referenced SO question, or even better add an even more evident case? –  NotAUser Dec 11 '12 at 15:15
@user1638891: Search prolog-dif - and please retag should you find other examples I missed. –  false Dec 11 '12 at 15:18

Well for one thing, the name should be more declarative, like equality_truth/2.

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Mat, do you refer to dif/2, I presume... –  CapelliC Dec 2 '12 at 23:03
I mean instead of equality_reified/2, it should be called more declaratively for example equality_truth/2 or maybe even equality_true/2 (since "false" as second argument can hardly be called a "truth"). "Reified" has the connotation that somebody did something, which is more imperative than declarative. We should choose a name with a connotation that something holds. –  mat Dec 3 '12 at 20:46
_truthvalue, _bool. –  false Dec 3 '12 at 23:05

While this answer is somewhat beside the point of your actual question, I'm sceptical about your premise. I don't think the inefficiency you're referring to with respect to occurrences/3 stems strictly from the use of (in-)equality in the definition that was given, which I wouldn't refer to as 'flawless' (what do you mean by this, anyway?). Instead, I think a tighter definition could be used to improve efficiency. For instance, if I were to write a definition for something like occurrences(+Val, +List, ?Occ), I would, stating with the base case, write:

occurrences(_, [], []).

Since certain Prolog implementations index only on the first argument, I'd opt to cut here with the full knowledge that no other cases/clauses will be relevant, giving:

occurrences(_, [], []) :- !.

Subsequent clauses now only deal with the case where the provided value (which may be a var) matches the head of the input list, or not:

% no match
occurrences(X, [Y|L], R) :-
X \== Y, !,
occurrences(X, L, R).

% match, by exclusion of all other cases
occurrences(X, [Y|L], [Y|R]) :-
occurrences(X, L, R).

The execution of this definition of occurrences/3 will not leave any unnecessary choicepoints, thus limiting the depth of the call stack to about the size of the input list.

Note that the corresponding pure definition does indeed leave many choicepoints, as you already suggest:

occurrences(_, [], []).
occurrences(X, [Y|L], R) :-
X \== Y,
occurrences(X, L, R).
occurrences(X, [Y|L], [Y|R]) :-
X == Y,
occurrences(X, L, R).

However, I'd argue that redefining (in-)equality using cut ! like you've suggested in your edit is also impure, defeating the purpose of maintaining purity. If you consider the use of implication (->) to be pure, I can suggest the following:

occurrences(V, L, O) :-
(L == [] ->
O = []
;   L = [X|Ls],
(V \== X ->
O = S
;   O = [X|S]
),
occurrences(V, Ls, S)
).

However, note that A -> B ; C is often implemented simply as A, !, B or C, so may also be considered impure.

Interestingly, the Mercury language has a pure logic syntax and the Mercury compiler is quite a clever one -- with some declarations about predicate mode and determinism, it can behave quite differently in execution, as if to automatically insert cuts in the right places for efficiency. However, this is of course a different language to Prolog ;-)

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I did say "flawless from a declarative viewpoint" not just flawless. –  false Dec 12 '12 at 11:32
Your mode declaration is ambiguous. Does + mean sufficiently instantiated or does it mean ground? In your case it should mean ground. –  false Dec 12 '12 at 11:41
Mercury is good for ground terms. But not more than that. –  false Dec 12 '12 at 11:49