# Four-color theorem in Prolog (using a dynamic predicate)

I'm working on coloring a map according to the four-color theorem (http://en.wikipedia.org/wiki/Four_color_theorem) with SWI-Prolog. So far my program looks like this:

``````colour(red).
colour(blue).

map_color(A,B,C) :- colour(A),
colour(B),
colour(C),
C \= B,
C \= A.
``````

(the actual progam would be more complex, with 4 colors and more fields, but I thought I'd start out with a simple case)

Now, I want to avoid double solutions that have the same structure. E.g. for a map with three fields, the solution "red, red, blue" would have the same structure as "blue, blue, red", just with different color names, and I don't want both of them displayed.

So I thought I would have a dynamic predicate solution/3, and call assert(solution(A,B,C)) at the end of my map_color predicate. And then, for each solution, check if they already exist as a solution/3 fact. The problem is that I would have to assert something like solution(Color1,Color1,Color2), i.e. with variables in order to make a unification check. And I can't think of a way to achieve this.

So, the question is, what is the best way to assert a found solution and then make a unification test so that "red, red, blue" would unify with "blue, blue, red"?

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To build relation between variables:

``````mask_helper(_, _, [], []).
A \= X,

``````

``````?- mask([red,red,blue],X).
X = [_G300, _G300, _G306] .
``````

but:

``````?- mask([red,red,blue],X), mask([blue,red,red],Y), X=Y.
X = [_G27, _G27, _G27],
Y = [_G27, _G27, _G27].
``````

I.e. there is no relation about `Color1 \= Color2` if you will use `assert` (without rule body).

You may consider somethin like ordering of assigning colours (pretty popular approach):

``````colour(red). colour(green). colour(blue).

colour_order(red, red).
colour_order(red, green).
colour_order(red, blue).
colour_order(green, green).
colour_order(green, blue).

colour_code([]).
colour_code([X]):- colour(X).
colour_code([X|[Y|T]]):-
colour_order(X,Y),
colour_code([Y|T]).

map_color(A,B,C):-
colour_code([A,B,C]),
C \= B, C \= A.
``````

But again you will never get result "red, blue, red" if your conditions will be `A \= B, B \= C`.

``````unify([], [], _).
unify([X|Xs], [Y|Ys], M):-
member((X=Z), M), !,
Z = Y,
unify(Xs, Ys, M).

unify([X|Xs], [Y|Ys], M):-
% X is not assigned yet
not(member((_=Y),M)), % Y is not used as well
unify(Xs, Ys, [(X=Y)|M]).
``````

Than you can compare:

``````?- unify([red,red,blue],[blue,blue,red],[]).
true.

?- unify([red,red,blue],[blue,blue,blue],[]).
false.

?- unify([red,red,blue],[blue,red,red],[]).
false.
``````
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I think that the simplest solution is to say that A has always the color red (for example).

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