ortools-clone/examples/csharp/crossword.cs

//
// Copyright 2012 Hakan Kjellerstrand
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//     http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.

using System;
using System.Collections;
using System.IO;
using System.Text.RegularExpressions;
using Google.OrTools.ConstraintSolver;


// Note: During compilation, there are a couple of
//       warnings about assigned but never used variables.
//       It's the characters a..z so it's quite benign.


public class Crossword
{

  /**
   *
   * Solving a simple crossword.
   * See http://www.hakank.org/or-tools/crossword2.py
   *
   *
   */
  private static void Solve()
  {
    Solver solver = new Solver("Crossword");

    //
    // data
    //
    String[] alpha = {"_","a","b","c","d","e","f",
                      "g","h","i","j","k","l","m",
                      "n","o","p","q","r","s","t",
                      "u","v","w","x","y","z"};

    int a=1;  int b=2;  int c=3; int d=4;  int e=5;  int f=6;
    int g=7;  int h=8;  int i=9; int j=10; int k=11; int l=12;
    int m=13; int n=14; int o=15; int p=16; int q=17; int r=18;
    int s=19; int t=20; int u=21; int v=22; int w=23; int x=24;
    int y=25; int z=26;

    const int num_words = 15;
    int word_len = 5;

    int[,] AA = {{h, o, s, e, s},  //  HOSES
                 {l, a, s, e, r},  //  LASER
                 {s, a, i, l, s},  //  SAILS
                 {s, h, e, e, t},  //  SHEET
                 {s, t, e, e, r},  //  STEER
                 {h, e, e, l, 0},  //  HEEL
                 {h, i, k, e, 0},  //  HIKE
                 {k, e, e, l, 0},  //  KEEL
                 {k, n, o, t, 0},  //  KNOT
                 {l, i, n, e, 0},  //  LINE
                 {a, f, t, 0, 0},  //  AFT
                 {a, l, e, 0, 0},  //  ALE
                 {e, e, l, 0, 0},  //  EEL
                 {l, e, e, 0, 0},  //  LEE
                 {t, i, e, 0, 0}}; //  TIE

    int num_overlapping = 12;
    int[,] overlapping = {{0, 2, 1, 0},  //  s
                          {0, 4, 2, 0},  //  s

                          {3, 1, 1, 2},  //  i
                          {3, 2, 4, 0},  //  k
                          {3, 3, 2, 2},  //  e

                          {6, 0, 1, 3},  //  l
                          {6, 1, 4, 1},  //  e
                          {6, 2, 2, 3},  //  e

                          {7, 0, 5, 1},  //  l
                          {7, 2, 1, 4},  //  s
                          {7, 3, 4, 2},  //  e
                          {7, 4, 2, 4}}; //  r

    int N = 8;

    //
    // Decision variables
    //
    // for labeling on A and E
    IntVar[,] A = solver.MakeIntVarMatrix(num_words, word_len,
                                          0, 26, "A");
    IntVar[] A_flat = A.Flatten();
    IntVar[] all = new IntVar[(num_words * word_len) + N];
    for(int I = 0; I < num_words; I++) {
      for(int J = 0; J < word_len; J++) {
        all[I * word_len + J] = A[I,J];
      }
    }

    

    IntVar[] E = solver.MakeIntVarArray(N, 0, num_words, "E");
    for(int I = 0; I < N; I++) {
      all[num_words * word_len + I] = E[I];
    }



    //
    // Constraints
    //
    solver.Add(E.AllDifferent());

    for(int I = 0; I < num_words; I++) {
      for(int J = 0; J < word_len; J++) {
        solver.Add(A[I,J] == AA[I,J]);
      }
    }

    // This contraint handles the overlappings.
    //
    // It's coded in MiniZinc as
    //
    //   forall(i in 1..num_overlapping) (
    //      A[E[overlapping[i,1]], overlapping[i,2]] =
    //      A[E[overlapping[i,3]], overlapping[i,4]]
    //   )
    // and in or-tools/Python as
    //   solver.Add(
    //      solver.Element(A_flat,E[overlapping[I][0]]*word_len+overlapping[I][1])
    //      ==
    //      solver.Element(A_flat,E[overlapping[I][2]]*word_len+overlapping[I][3]))
    //
    for(int I = 0; I < num_overlapping; I++) {
      solver.Add(
          A_flat.Element(E[overlapping[I,0]] * word_len + overlapping[I,1]) ==
          A_flat.Element(E[overlapping[I,2]] * word_len + overlapping[I,3]));
    }



    //
    // Search
    //
    DecisionBuilder db = solver.MakePhase(all,
                                          Solver.INT_VAR_DEFAULT,
                                          Solver.INT_VALUE_DEFAULT);

    solver.NewSearch(db);

    while (solver.NextSolution()) {
      Console.WriteLine("E: ");
      for(int ee = 0; ee < N; ee++) {
        int e_val = (int)E[ee].Value();
        Console.Write(ee + ": (" + e_val + ") ");
        for(int ii = 0; ii < word_len; ii++) {
          Console.Write(alpha[(int)A[ee,ii].Value()]);
        }
        Console.WriteLine();
      }

      Console.WriteLine();
    }

    Console.WriteLine("\nSolutions: {0}", solver.Solutions());
    Console.WriteLine("WallTime: {0}ms", solver.WallTime());
    Console.WriteLine("Failures: {0}", solver.Failures());
    Console.WriteLine("Branches: {0} ", solver.Branches());

    solver.EndSearch();

  }



  public static void Main(String[] args)
  {
    Solve();
  }
}