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union([H|T], SET2, RESULT) :- member(H,SET2), union(T,SET2,RESULT).    
union([H|T], SET2, [H|RESULT]) :- not(member(H,SET2)), union(T,SET2,RESULT).

I am able to understand that it is traversing the first list and adding based on whether the element is a member of 2nd list or not. I got the logic. However, the workflow is mysterious to me where it adds the elements of "second list" to the result once the first list is exhausted.

Please could someone take a simple example like union([1,2], [2,3], Result), and explain the workflow.

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thanks for the edit.. it made it much more clear.. –  Firefox Oct 17 '12 at 4:35

3 Answers 3

up vote 6 down vote accepted

I'll assume that you are calling union/3 with the first and second arguments instantiated. The third argument can be either uninstantiated upon calling and will be unified at return with the union of the two lists or if it's already instantiated it can be used to check whether it matches the (ordered) union of the first two lists.

The first clause states that if the second argument is the empty list and the first list has at least one element then the union is just this first list. Likewise, the second clause states that if the first argument is the empty list and the second list has at least one element then the union is just this second list.

The third clause recurses over the first list and checks the second list to see if the item is already there. In that case it just calls itself with the tail of the first list.

The fourth clause tests the head of the first list to check that it is not contained in the second list and calls recursively with the tail (just like the third clause). However upon return of recursion it adds the item to the head of the third list, thus adding the item to the union.

Note that in your implementation, the union of two empty sets will always fail. You can fix this by modifying the first or second clause to allow an empty list, or the add another clause for this case. E.g.


Now let's see what happens when we call union([1,2],[2,3], Result):

The first two clauses will fail to match as neither of them are the empty list.

We enter the third clause and check to see that element 1 is not a member of the second list thus failing there.

We try now the fourth clause and test that element 1 i not in the second list, so we call union([2], [2,3], Result), we mark this execution point (*1).

Again the two first clauses will fail to match, so we enter the third clause. Here we test that indeed element 2 is contained in the second list so we call union([], [2,3], Result), we mark this execution point (*2)

Now the first clause fails as the first argument is the empty list. We now enter the second clause unifying the third argument with the second list ([2,3]).

At this point we return to (*2) where now Result gets instantiated with [2,3]. This clauses end there so we bound the third argument with [1,2,3], and we return to (*1).

We are now at (*1) where Result and therefore the third argument gets instantiated with [1,2,3].

This gives us the first result [1,2,3].

However a choice point was left when we succedded in (*2), so if we ask Prolog to search for another answer it still has to try the fourth clause of union([2],[2,3], Result).

So we enter the fourth clause to test if 2 is not a member of [2,3] which fails, so Prolog will tell us that there are no other answers.

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Superb... reading just 'once' was enough.. you certainly are a great teacher. Thanks a lot :) –  Firefox Oct 17 '12 at 4:34

In my answer answer to a related question "Intersection and union of 2 lists" I present a logically pure implementation of intersection and union.

Unlike the other answers to your question the pure variant is monotone and thus stays logically sound when used with non-ground terms.

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You are not inspecting SET2, thus assuming there are not duplicates in it, then the base recursion can be the single predicate

union([], U, U).

@gusbro already explained that when H doesn't belong to SET2 it is placed in (local) front of result after the recursive call succeeded.

The explanation should clear your doubts, but please note that not/1 essentially repeat the very same test already performed in the previous (failed) call. Then a better code could be

union([H|T], SET2, RESULT) :-
   member(H,SET2), !, % note the commit
union([H|T], SET2, [H|RESULT]) :- 
   % useless now 
   % not(member(H,SET2)),

This is equivalent to your code, assuming member/2 is side effects free (and it is).

not/1 can be implemented using !/0.

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thanks for the reply.. I think I understood the trick you were pointing out.. it was helpful, helped me understand the use case of '!'.. However, having the check (at least commented out) improves the readability.. –  Firefox Oct 17 '12 at 4:40

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