# Perfoming member check on a difference list, but how?

I tried to answer another question (wrongly though) and this led to a question on "difference lists" (or "list differences", which seems a more appropriate name, unless "Escherian Construction" isn't preferred)

We have a fully ground list of elements `obj(X,Y)` (both `X` and `Y` ground). We want to retain only the first `obj(X,_)` where `X` hasn't been encountered yet when going through the list front to back. Those "first elements" must appear in order of appearance in the result.

Let's specify the problem through test cases:

``````% Testing

:- begin_tests(collapse_dl).

test(one)   :- collapse_dl([],[]).
test(two)   :- collapse_dl([obj(a,b)],
[obj(a,b)]).
test(three) :- collapse_dl([obj(a,b),obj(a,c)],
[obj(a,b)]).
test(four)  :- collapse_dl([obj(a,b),obj(a,c),obj(b,j)],
[obj(a,b),obj(b,j)]).
test(five)  :- collapse_dl([obj(a,b),obj(a,c),obj(b,j),obj(a,x),obj(b,y)],
[obj(a,b),obj(b,j)]).

:- end_tests(collapse_dl).

rt :- run_tests(collapse_dl).
``````

Now, this is easy to implement using filtering, list prepend and `reverse/2`, but what about using difference lists and list append?

however, I'm not able to get the `seen/2` predicate to work. It checks whether `obj(A,_)` is already in the difference list. But what's a proper termination for this predicate?

``````% This is called

collapse_dl([],[]) :- !.
collapse_dl([X|Xs],Out) :-
Dlist = [X|Back]-Back,        % create a difflist for the result; X is surely in there (as not yet seen)
collapse_dl(Xs,Dlist,Out).    % call helper predicate

% Helper predicate

collapse_dl([],Ldown,Lup):-               % end of recursion; bounce proper list back up
Ldown = Lup-[].                        % the "back" of the difflist is unified with [], so "front" becomes a real list, and is also Lup

collapse_dl([obj(A,_)|Objs],Ldown,Out) :-
seen(obj(A,_),Ldown),                  % guard: already seen in Ldown?
!,                                     % then commit
collapse_dl(Objs,Ldown,Out).           % move down chain of induction

collapse_dl([obj(A,B)|Objs],Ldown,Out) :-
\+seen(obj(A,_),Ldown),                % guard: not yet seen in Ldown?
!,                                     % then commit
Ldown = Front-Back,                    % decompose difference list
Back = [obj(A,B)|NewTail],             % NewTail is fresh! Append via difflist unification magic
collapse_dl(Objs,Front-NewTail,Out).   % move down chain of induction; Front has been refined to a longer list

% Membership check in a difference list

seen(obj(A,_),[obj(A,_)|_Objs]-[]) :- !.  % Yup, it's in there. Cut retry.
seen(Obj,[_|Objs]-[]) :- ...              % But now???
``````

# Update

With Paulo's code snippet:

``````
% Membership check in a difference list

seen(Element, List-Back) :-
List \== Back,
List = [Element|_].
seen(Element, List-Back) :-
List \== Back,
List = [_| Tail],
seen(Element, Tail-Back).
``````

So, term equivalence, or dis-equivalence in this case, is the solution!

We now pass all the test.

Try (taken from Logtalk `difflist` library object):

``````member(Element, List-Back) :-
List \== Back,
List = [Element|_].
member(Element, List-Back) :-
List \== Back,
List = [_| Tail],
member(Element, Tail-Back).
``````
• All right, I sort get it.. The key is term equivalence ... I have retconned my code to fit this as it had a few other problems. Apr 7, 2020 at 19:46

`memberchk/2` should do it. Using the approach from here,

``````%% collapse_dl( ++Full, -Short )
collapse_dl( [obj(K,V) | A], B ) :-
memberchk( obj(K,X), B ),
( X = V -> true ; true ),
collapse_dl( A, B ).
collapse_dl( [], B ) :-
length( B, _), !.
``````

Doing what (functional) Prolog does best, instantiating an open-ended list in a top-down manner.

Passes the tests included in the question.

``````%% collapse_dl( ++Full, -Short )
collapse_dl( [obj(K,V) | A], B ) :-
format("Enter : ~w relatedto ~w\n", [[obj(K,V) | A], B]),
% Necessarily find  (find or insert)  obj(K, X) (thanks to the
%  uninstantiated X) in list B which has an "unobserved" tail:
memberchk( obj(K,X), B ),
% Unify X with V if you can; ignore failure if you can't!
( X = V -> true ; true ),
format("Mid   : ~w relatedto ~w\n", [[obj(K,V) | A], B]),
collapse_dl( A, B ),
format("Return: ~w relatedto ~w\n", [[obj(K,V) | A], B]).

collapse_dl( [], B ) :-
format("Termination: From unobserved-tail-list ~w ",[B]),
length(B, _),
format("to ~w (and don't come back!)\n",[B]),
!.
``````

Because of the added printouts this code is no longer tail-recursive. The original is, and so has no "return" in its trace: it just goes forward and stops working right away when the input list is traversed to its end.

See more about the distinction e.g. here.

This "open-ended list" technique is not difference list, but the two are very closely related. And we don't actually need the explicit tail anywhere here, except for the final freezing. So we just do the O(n) `length` call instead of the explicit O(1) `Tail = []` we'd do with difference lists, no biggie.

Of bigger impact is the choice of list instead of e.g. tree data structure. Trees can be open-ended too, just need to use `var/1` here and there. Next step is the tree's structure. Top-down open-leaved tree can't be rotated (as all the calls reference the same top node) so its depth will depend on the input's orderedness. To maintain good balance the trees need to be rotated on occasion, hence closed; and we're back to the traditional state-passing code, were each call gets two tree arguments -- the one before update, and the other after it: the

``````    upd(T1, T2), next(T2, T3), more(T3, T4), ...
``````

kind of thing. It ought to be used in real code. There are some libraries that do that.

This answer's code is simplistic, in order to be simple and illustrative.

• what is that other question you mention in the post? @David Apr 8, 2020 at 9:01
• It was this one: stackoverflow.com/questions/61079223/… and I solved a different problem (namely, the one in the present question) Apr 8, 2020 at 9:04
• funny, just now realized it says "member check" in the title. :) Apr 8, 2020 at 9:12
• check out the linked one(s) for context. but do ask here, if you feel like it. :) Apr 8, 2020 at 9:12
• Ok, got it. Added a version with printouts. Apr 8, 2020 at 9:57

Since I currently need it, I got a simpler solution. Assuming the difference list is open, means for the pair `List-Back`, we have `var(Back)`. Then we can short cut, only passing `List`:

``````member_open(_, List) :- var(List), !, fail.
member_open(Element, [Element|_]).
member_open(Element, [_|List]) :- member_open(Element, List).
``````

If we want to append an element to the `List`, since for example we didn't find it via member_open/2, we simply make `Back = [NewElement|Back2]` and continue with `Back2`.

Here is `variables/2` (ISO `term_variables/2`) written this way, so that it doesn't need reverse/1:

``````variables(T, L) :-
variables(T, B, B, B2),
B2 = [],
L = B.

variables(V, L, B, B) :- var(V), member_open(W, L), V == W, !.
variables(V, L, [V|B], B) :- var(V), !.
variables(T, L, B, B2) :-
T =.. [_|A],
variables_list(A, L, B, B2).

variables_list([T|A], L, B, B2) :-
variables(T, L, B, H),
variables_list(A, L, H, B2).
variables_list([], _, B, B).
``````

Seems to work:

``````?- variables(f(X,g(X,Y),Y), L).
L = [X, Y].
``````
• `member_open( E, OL) -> Back=Back2 ; Back=[E|Back2]` is the same as just `member(E,OL)`, I think. with open lists, `member` can't fail -- if the element weren't in the instantiated portion, it is added at the tail. so this seems to be doing more work explicitly that would otherwise get done for us behind the scenes.... except that it gives us the handle on the back pointer, in case perhaps it is needed for something... yes building lists top-down seems much better in any language, and it is so easy in Prolog. :) Jul 1, 2021 at 12:45
• Thats a bold claim. But it is not the same, since member/2 doesn't expose Back, Back2. Also Also member/2 doesn't expose which branch was taken, you could not write variables/2 with member/2. Also member/2 would infinitely often backtrack over the end of an open list, whereas member_open/2 doesn't do that.
– user502187
Jul 1, 2021 at 13:14
• yes, I write about the back pointer, too. as for backtracking, a cut would take care of that (like there is one in member_open's base case clause, too). Jul 1, 2021 at 13:38
• You wrote an if-then-else with member_open/2 and parameter Back and Back2, and said its the same as member/2. But already the parameters Back and Back2 are missing from the member/2 call. These parameters are also missing if you use once(member(E,OL)). So I don't see any way to fix that.
– user502187
Jul 1, 2021 at 13:54