I'm trying to write a function that recursively adds the first two items in a List, and returns when one item remains. Example:

addList([1,2,3,4], X) 
x = [10]

(Steps here would be: [1,2,3,4] -> [3,3,4] -> [6,4] -> [10] )

This is what I have:

addList([H|[H2|T]], []) :- L is H+H2, addList(T, [L|T]).
addList([H|T], [H2|_]) :- L is H+H2, addList(T, [L|T]).

In my mind, this would do something like the following:

addList([1,2,3,4], X).
L=1+2 --> addList([3,4], [3,3,4])
L=3+3 --> addList([4], [6, 4])
L=6+4 --> addList([], [10])

This actually causes an error - "Arguments are not sufficiently instantiated"

If I make the first addList into addList([],[_])., it'll output X = [] . first, then have the same error if I use ; to continue. It should end in false.

(After having the chain of X = [1,2,3,4] ; X = [3,3,4] ; X = [6,4] ; X = [10] ; false.


First, note that you can write [H|[H2|T]] equivalently as [H,H2|T].

Also, as far as I know in Prolog the preferred style is to use snake_case instead of camelCase.

add_list([H1,H2|T], []) :- ...

In the above clause, you already unifiy the second term with the empty list, and what happens in ... is just a way of checking if the relationship holds. The L that occurs in the body is only a local variable; likewise, the recursive call to add_list is not used to compute the "result" (the second parameter).

You expect the result to always be a singleton list containing the total sum of your values, except if the list is empty (in which case the result is empty). The base cases are then:

add_list([], []).
add_list([N], [N]).

The general case is necessarily something like:

add_list([H1,H2|T], [Sum]) :- ...

And you have to expression the recursive relationship in terms of H1, H2, T and Sum. In fact until you reach a base case you are likely to only pass down the second argument unmodified, so you do not need to write [Sum] explicitly, you could just write Res:

add_list([H1,H2|T], Res) :-
    add_list(..., Res).

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