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I made a Prolog program posAt(List1,P,List2) that tests whether the element at position P of List1 and List2 are equal:

posAt([X|Z],1,[Y|W]) :- X=Y.    
posAt([Z|X],K,[W|Y]) :- K>1, Kr is K - 1, posAt(X,Kr,Y).

When testing:

?- posAt([1,2,3],X,[a,2,b]).

I expected an output of X=2 but instead I got the following error: ERROR: >/2: Arguments are not sufficiently instantiated

Why am I getting this error?

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A good idea is normally to 'accept' the best answer submitted. This can be done by clicking on the tick symbol for an answer. –  Chetter Hummin Mar 24 '12 at 5:36

2 Answers 2

A Prolog predicate is a relation between arguments, and your statement

the element at position P of List1 and List2 are equal

is clearly an example where multiple solutions are possible.

?- posAt([1,2,3],X,[1,5,3,7]).
X = 1.


So the answer from sharky, while clearly explains why the technical error arises, requires a small correction:

posAt([X0|_], Pos, Pos, [X1|_]) :-
    X0 == X1.

Now it works as expected.

?- posAt([1,2,3],X,[1,5,3,7]).
X = 1 ;
X = 3 ;

Writing simple predicates for list processing it's a very valuable apprenticeship practice, and the main way to effectively learn the language. If you are incline also to study the available library predicates, here is a version using nth1/3 from library(lists)

posAt(L0, P, L1) :-
    nth1(P, L0, E), nth1(P, L1, E).

This outputs:

?- posAt([1,2,3],X,[1,5,3,7]).
X = 1 ;
X = 3.

Could be interesting to attempt understanding why in this case SWI-Prolog 'top level' interpreter is able to infer the determinacy of the solution.

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+1: Thanks for picking up my error! I like the technique using nth1/3 too, nice one. –  sharky Mar 20 '12 at 22:49

This occurs because, when the subgoal K > 1 is evaluated by Prolog, K is still an unbound variable and not a number. Standard Prolog can't (won't) evaluate the true/false value of numerical range restrictions such as this when they aren't ground (as opposed to constraint solvers like CLP, which permit this but work differently).

Consider this solution:

posAt(L0, Pos, L1) :- 
    posAt(L0, 1, Pos, L1).

posAt([X0|_], Pos, Pos, [X1|_]) :-
    X0 == X1.

posAt([_|X0s], CurrPos, Pos, [_|X1s]) :-
    NextPos is CurrPos + 1,
    posAt(X0s, NextPos, Pos, X1s).

The first predicate posAt/3 sets up the initial condition: lists as position 1, and calls posAt/4 to iterate though the list.

The first clause of posAt/4 is a match condition: the elements in both lists at the same position are equal. In this case, the current position variable is unified with Pos, the result.

If the above clause failed because the list elements X0 and X1 were unequal, the list position CurrPos is incremented by one, and a recursive call to posAt/4 starts processing again at the next pair of items.

EDIT: Removed incorrect cut in first clause of posAt/4 (thanks to @chac for the pickup)

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