Constraint-programming: Fill grid with colors following pattern rules

I'm new to constraint-programming (coming from c#) and I'm trying to solve this problem. Unfortunately I don't have a name for this kind of puzzle so I'm not sure what to search for. The closest examples I can find are Nonogram and Tomography puzzles.

Puzzle description: The player is given an empty game board (varying size) that they must fill with n-colors, using clue patterns for the rows and columns. Each clue pattern is the sequence of colors in that row/col but with consecutive duplicates removed.

Here is an example easy small 4x4 grid with 3 colors:

``````rbg,rbr,grb,bgbg       <- (top-to-bottom column constraints)

_,_,_,_     rgb    <- (row constraints)
_,_,_,_     brg
_,_,_,_     b
_,_,_,_     grbg
``````

Solutions (2):

``````    r,r,g,b
b,?,r,g
b,b,b,b
g,r,b,g
``````

? Can be either red or blue but not green.

Pattern examples below. Examples given 6-length sequences to pattern:

``````aaaaaa -> a
aabbcc -> abc
abbbbc -> abc
cabbbc -> cabc
bbbaac -> bac
abbaab -> abab
abcabc -> abcabc
``````

Examples given pattern to potential solution sequences:

``````abc -> abc (3 length solution)
abc -> abcc, abbc, aabc (4 length solutions)
abc -> abccc, abbcc, abbbc, aabbc, aaabc (5 length solutions)
``````

I've tried to solve it in C# or-tools and MiniZinc but the biggest problem I have is building the constraints. I can generate the patterns from a sequence (in c# imperative way) but then how to turn that into a constraint?

How I'm thinking about it: generate all potential sequences from each clue pattern. Then make a constraint for the corresponding row/col that says it must be one of those sequences.

Example from top row in above puzzle: rgb to [4-length sequences] -> rgbb, rggb, rrgb, and then add a constraint for that row: must equal one of these sequences.

=====================================

Edit after some progress:

This MiniZinc correctly solves the top row for the pattern abc which has 3 solutions of 4 length: aabc, abbc, abcc.

``````include "globals.mzn";

array [1..4, 1..4] of var 1..3: colors;

constraint regular(row(colors, 1), 4, 3,
[|
% a, b, c
2,0,0| % accept 'a'
2,3,0| % accept 'a' or 'b' ?
0,3,4| % accept 'b' or 'c' ?
0,0,4| % accept 'c'
|], 1, {4});

% Don't care about rest of grid for now.
constraint forall(i,j in 1..4 where i > 1) (row(colors, i)[j] = 1);

solve satisfy;

output [show(colors)];
``````

However I'm not sure how to handle larger grids with many patterns other than hardcoding everything like this. I will experiment a bit more.

• You might get soms inspiration from my MiniZinc model for generating the regular constraints for the nonogram solver: hakank.org/minizinc/nonogram_create_automaton2.mzn It's the predicate make_automaton that do the work. Note: It's not pretty and it's not even small... – hakank Mar 5 at 11:09
• @hakank Wow... that is very dense code! But I think I understand the general idea is to construct these transition tables. I also found another of your examples that helped me a lot: regex Thank you! – Jaxe Mar 5 at 11:45

The constraints you are talking about seem to be easily represented as regular expressions. For example your `abc` example with varying length can be caught using the regular expression `abc.*`, which requires one `a` then one `b`, and then one `c`, it will accept anything else afterwards.

In MiniZinc these kinds of constraints are expressed using the `regular` predicate. The regular predicate simulates an automaton with accepting states. By providing the allowed state-transitions the model is constraint.

The example expression `abc.*` would be enforced by the following constraint item:

``````% variables considered, nr states, input values
constraint regular(VARS, 4, 1..3, [|
% a, b, c
2,0,0| % accept 'a'
0,3,0| % accept 'b'
0,0,4| % accept 'c'
4,4,4| % accept all
|], 1, {4}); % initial state, accepting states
``````
• Thanks this helped a lot. – Jaxe Mar 5 at 10:25
• The regular predicate isn't quite right but I was able to edit it to something that kinda works. I will edit my original question to include my progress. – Jaxe Mar 5 at 10:27
• Currently there is no tool that converts a regular expression or an automata to a `regular` predicate. We would love to offer such an tool, but we're limited by development time. – Dekker1 Mar 7 at 0:46

In Prolog(language), I use `DCG` form to describe such problems. It is extended `BNF` form. So I suggest finding approach with Extended BNF Form in your environment.

SWI-Prolog example:

``````color_chunk_list(Encoded,Decoded):-
phrase(chunk_list(Encoded),Decoded),
chk_continuity(Encoded).

chunk_list([])-->[].
chunk_list([First|Rest])-->colorrow(First),chunk_list(Rest).

colorrow(Color)-->[Color],colorrow(Color).
colorrow(Color)-->[Color].

chk_continuity([First,Second|Rest]):-First \= Second,chk_continuity([Second|Rest]).
chk_continuity([_]).
``````

In this program, encodings and decodings are bidirectional.

Tests:

``````?- length(L,4),color_chunk_list([r,g],L).
L = [r, r, r, g] ;
L = [r, r, g, g] ;
L = [r, g, g, g] ;
false.

?- length(L,6),color_chunk_list([a,b,c],L).
L = [a, a, a, a, b, c] ;
L = [a, a, a, b, b, c] ;
L = [a, a, a, b, c, c] ;
L = [a, a, b, b, b, c] ;
L = [a, a, b, b, c, c] ;
L = [a, a, b, c, c, c] ;
L = [a, b, b, b, b, c] ;
L = [a, b, b, b, c, c] ;
L = [a, b, b, c, c, c] ;
L = [a, b, c, c, c, c] ;
false.

?- color_chunk_list(L,[a,a,b,b,c,c]).
L = [a, b, c] ;
false.

?- color_chunk_list(L,[b,r,b,r,r,g,g,b]).
L = [b, r, b, r, g, b] ;
false.
``````

In ECLiPSe, which is prolog based CLP system (not IDE one), above predicate(`color_chunk_list`) can be turned into clp constraint with `propia` mechanism and can genarate clp `propagation`.