# SICStus Prolog Lists

Having trouble understanding how Prolog works. I'm tryig to write a rule that takes three lists of integers as input (representing sets) and puts the integers that belong to both the first and second list in the third list.

Example:

``````?-inter([10,20,30,40],[10,50,40,60], List3 )
List3 = [10, 40]
``````

So far I have this, that can recognize if a list contains a certain letter:

``````mymember(X,[X|T]).
mymember(X,[H|T]) :- mymember(X,T).
``````
-

There's actually an inbuilt library to sort that all out for you, known as ordsets.

``````inter(X, Y, Z) :-
list_to_ord_set(X, L1),
list_to_ord_set(Y, L2),
ord_intersection(L1, L2, Z).
``````

Using your example input you get the following

``````| ?- inter([10,20,30,40],[10,50,40,60],X).
X = [10,40] ? ;
no
``````
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I get an error saying "list_to_ord_set/2 does not exist"... – user1657568 Sep 9 '12 at 3:15
Did you load the library? use_module(library(ordsets)) to load it – WhaleFanny Sep 9 '12 at 3:18

`inter(Xs, Ys, Zs)` will be true when each element in Zs also is in Xs and in Ys.

But Zs are unknown, then a more constructive approach is required. Here it is: `iterate on Xs and store in Zs each element that is in Ys`.

An example of iteration is mymember/2, you can see that it requires a recursive predicate. The other idiomatic part of the above statement is `store in Zs`, Prolog has a peculiar way to do such things, using pattern matching.

``````inter([X|Xs], Ys, [X|Zs]) :-
mymember(X, Ys), inter(Xs, Ys, Zs).
``````

You will need to complete inter/3 with other 2 clauses: base recursion, i.e. when all Xs elements have been processed, and the case where X is not a member of Ys.

-

Try something like this, using the builtins `member/2` and `setof\3`:

``````set_intersection( As , Bs , Xs ) :-
set_of( X , ( member(X,As) , member(X,Bs) ) , Xs )
.
``````

One should note that this will fail if the lists `As` and `Bs` have no elements in common. An alternative would be use `findall/3` rather than `set_of/3`. `findall/3` will hand back and empty list rather than failure if the goal is not satisfied:

``````set_intersection( As , Bs , Xs ) :-
findall( X , ( member(X,As) , member(X,Bs) ) , Xs )
.
``````

However `findall/3` returns a bag (duplicates are allowed) rather than a set (no duplicates allowed), so if your two source lists aren't sets, you won't get a set out.

`member/2` is a builtin predicate that unifies its first argument with an element of the list — the equivalent of

``````member(X,[X|_).
member(X,[_|Xs) :- member(X,Xs) .
``````

And, finally, as @chac noted in his answer, you can recursively traverse the list.

``````set_intersection( [] , _ , [] ) .            % the intersection of the empty set with anything is the empty set.
set_intersection( [A|As] , Bs , [A|Xs] ) :-  % if the list is non-empty,
member(A,Bs) ,                             % - and A is a member of the 2nd set
! ,                                        % - we cut off alternatives at this point (deterministic)
set_intersection( As , Bs , Xs )           % - and recurse down on the tail of the list.
.
set_intersection( [_|As] , Bs , Xs ) :-      % if the list is non-empty, and A is NOT a embmer of the 2nd set
set_intersection( As , Bs , Xs )           % we just recurse down on the tail of the list.
.
``````

@chac's technique builds the result list as he goes, something like:

``````[a|X]
[a,b|X]
[a,b,c|X]
``````

The final unification, the special case of the empty list unifies the unbound tail of the list with `[]` making the list complete, so the final `[a,b,c|X]` becomes

``````[a,b,c]
``````

A little prolog magic. An alternative that might be easier to understand is to use a worker predicate with an accumulator:

``````%
% set_intersection/3: the public interface predicate
%
set_intersection( As , Bs , Xs ) :-
set_intersection( As , Bc , [] , T ) % we seed our accumulator with the empty list here
.

%
% set_intersection/4: the private worker bee predicate
%
set_intersection( []     , _  , T , Xs ) :-   % since our accumulator is essentially a stack
reverse(T,Xs)                               % we need to reverse the accumulator to
.                                           % put things in the expected sequence
set_intersection( [A|As] , Bs , T  , Xs ) :-
member( A, Bs ) ,
! ,
T1 = [A|T] ,
set_intersection( As , Bs , T1 , Xs )
.
set_intersection( [_|As] , Bs , T , Xs ) :-
set_intersection( As , Bs , T , Xs )
.
``````
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