I have an assignment that seems out of scope of my class (I say this because they barely taught us anything about prolog), I have to write a prolog program to solve the game "Flow Free" on android. In the assignment it is called Numberlink. I could solve this in C++ in a hour but because I'm not too familiar with prolog it is giving me trouble. Here's what I would like to do:

  1. Make a list that holds a boolean to indicate whether it has been visited or used.
  2. Recursively search all possible paths from a given starting point to the end point using a breadth first search to find the shortest paths.
  3. Go from there I guess.

My attempt included searching the web on how to make a list. Of course prolog is not documented well at all anywhere so I came up blank and gave up. A friend told me to use maplist which I don't understand how I would use it to make a list including what I need.

Thanks in advance.

EDIT: Thanks for the link, but I was looking to make a 2D list to represent the board being played on. Function would look like this:

makeList(size, list):-

Where size is an integer representing the size of one dimension in the square list ex. (7x7).

  • Possible duplicate of Help With Prolog Lists – 0X0nosugar Jan 27 '16 at 17:08
  • 2
    Of course prolog is not documented well at all anywhere, really? – lurker Jan 27 '16 at 19:22
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    doesn't look like you are on the right track. Prolog is a declarative language. you should think about defining the relationship between each block, and then hit the solve button. – Fabricator Jan 27 '16 at 19:26

Here's an implementation of @CapelliC's solution. The code is self-explanatory. 2 blocks are connected if they are adjacent and have the same color, or adjacent to another connected block of the same color. (I used X and Y instead of row and column, it made writing the conditions at the end a little confusing.)

Solving in SWI-Prolog

enter image description here


connected(P1, P2, M, Visited) :-
    adjacent(P1, P2),
    maplist(dif(P2), Visited),
    color(P1, C, M),
    color(P2, C, M).
connected(P1, P2, M, Visited) :-
    adjacent(P1, P3),
    maplist(dif(P3), Visited),
    color(P1, C, M),
    color(P3, C, M),
    connected(P3, P2, M, [P3|Visited]).

adjacent(p(X,Y1), p(X,Y2)) :- Y2 is Y1+1.
adjacent(p(X,Y1), p(X,Y2)) :- Y2 is Y1-1.
adjacent(p(X1,Y), p(X2,Y)) :- X2 is X1+1.
adjacent(p(X1,Y), p(X2,Y)) :- X2 is X1-1.

color(p(X,Y), C, M) :-
    nth1(Y, M, R),
    nth1(X, R, C).

sol(M) :-
    M = [[1,_,_,_,1],
    connected(p(1,1), p(5,1), M, [p(1,1)]),
    connected(p(1,2), p(2,5), M, [p(1,2)]),
    connected(p(1,3), p(1,5), M, [p(1,3)]),
    connected(p(2,3), p(4,3), M, [p(2,3)]),
    connected(p(3,5), p(5,5), M, [p(3,5)]).

Sample query:

?- sol(M).
M = [[1, 1, 1, 1, 1],
     [2, 2, 2, 2, 2], 
     [3, 4, 4, 4, 2],
     [3, 2, 2, 2, 2], 
     [3, 2, 5, 5, 5]].
  • How about using maplist(dif(P3),Visited) instead of \+ member(P3,Visited) to preserve logical-purity? – repeat Jan 28 '16 at 0:21
  • 1
    great suggestion! I wasn't even aware of this construct. it's more declarative now. – Fabricator Jan 28 '16 at 0:28
  • s(X): I didn't know about it either up until last year, or so. No big deal, but it is kind of clever, and works out-of-the-box with (at least) with swi-prolog, sicstus-prolog, and yap. – repeat Jan 28 '16 at 1:51
  • By the way... Have you considered adding an independent second answer based on clpfd? I'd really like to know how "old school Prolog" and "nu school Prolog" solutions perform---compared head to head with different problem instances ranging from easy, medium, difficult, to hard... – repeat Jan 28 '16 at 1:55
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    image was stolen from here. I won't be adding a solution based on clpfd because I have no idea how it works. there's still a lot of learning ahead for me. you're welcome to try the clpfd approach. – Fabricator Jan 28 '16 at 2:00

The declarative Prolog 'modus operandi' is based on non determinism, implemented by depth first search. Let's apply to this puzzle: M is the playground, a list of lists of free cells (variables) or integers (colors)

one_step(M) :-
  cell(M, X,Y, C),
  integer(C), % the selected cell is a color
  cell(M, X1,Y1, C). % bind adjacent to same color - must be free

cell(M, X,Y, C) :- nth1(Y,M,R), nth1(X,R,C).

% moves
delta(X,Y,X1,Y) :- X1 is X+1. % right
delta(X,Y,X1,Y) :- X1 is X-1. % left
delta(X,Y,X,Y1) :- Y1 is Y-1. % up
delta(X,Y,X,Y1) :- Y1 is Y+1. % down

what this does ? let's try on a 3x3 playground

?- M=[[_,9,_],[_,0,_],[_,_,9]],one_step(M).
M = [[_G1824, 9, 9], [_G1836, 0, _G1842], [_G1848, _G1851, 9]] ;
M = [[9, 9, _G1830], [_G1836, 0, _G1842], [_G1848, _G1851, 9]] ;
M = [[_G1824, 9, _G1830], [_G1836, 0, 0], [_G1848, _G1851, 9]] ;
M = [[_G1824, 9, _G1830], [0, 0, _G1842], [_G1848, _G1851, 9]] ;
M = [[_G1824, 9, _G1830], [_G1836, 0, _G1842], [_G1848, 0, 9]] ;
M = [[_G1824, 9, _G1830], [_G1836, 0, _G1842], [_G1848, 9, 9]] ;
M = [[_G1824, 9, _G1830], [_G1836, 0, 9], [_G1848, _G1851, 9]] ;

No need to declare grid size, check index boundaries, etc... when one_step/1 succeeds it has instantiated a free cell to an adjacent same color...

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