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sudoku_c.c
/* Copyright 2020, Gurobi Optimization, LLC */ /* Sudoku example. The Sudoku board is a 9x9 grid, which is further divided into a 3x3 grid of 3x3 grids. Each cell in the grid must take a value from 0 to 9. No two grid cells in the same row, column, or 3x3 subgrid may take the same value. In the MIP formulation, binary variables x[i,j,v] indicate whether cell <i,j> takes value 'v'. The constraints are as follows: 1. Each cell must take exactly one value (sum_v x[i,j,v] = 1) 2. Each value is used exactly once per row (sum_i x[i,j,v] = 1) 3. Each value is used exactly once per column (sum_j x[i,j,v] = 1) 4. Each value is used exactly once per 3x3 subgrid (sum_grid x[i,j,v] = 1) Input datasets for this example can be found in examples/data/sudoku*. */ #include <stdlib.h> #include <stdio.h> #include <string.h> #include "gurobi_c.h" #define SUBDIM 3 #define DIM (SUBDIM*SUBDIM) int main(int argc, char *argv[]) { FILE *fp = NULL; GRBenv *env = NULL; GRBmodel *model = NULL; int board[DIM][DIM]; char inputline[100]; int ind[DIM]; double val[DIM]; double lb[DIM*DIM*DIM]; char vtype[DIM*DIM*DIM]; char *names[DIM*DIM*DIM]; char namestorage[10*DIM*DIM*DIM]; char *cursor; int optimstatus; double objval; int i, j, v, ig, jg, count; int error = 0; if (argc < 2) { fprintf(stderr, "Usage: sudoku_c datafile\n"); exit(1); } fp = fopen(argv[1], "r"); if (fp == NULL) { fprintf(stderr, "Error: unable to open input file %s\n", argv[1]); exit(1); } for (i = 0; i < DIM; i++) { fgets(inputline, 100, fp); if (strlen(inputline) < 9) { fprintf(stderr, "Error: not enough board positions specified\n"); exit(1); } for (j = 0; j < DIM; j++) { board[i][j] = (int) inputline[j] - (int) '1'; if (board[i][j] < 0 || board[i][j] >= DIM) board[i][j] = -1; } } /* Create an empty model */ cursor = namestorage; for (i = 0; i < DIM; i++) { for (j = 0; j < DIM; j++) { for (v = 0; v < DIM; v++) { if (board[i][j] == v) lb[i*DIM*DIM+j*DIM+v] = 1; else lb[i*DIM*DIM+j*DIM+v] = 0; vtype[i*DIM*DIM+j*DIM+v] = GRB_BINARY; names[i*DIM*DIM+j*DIM+v] = cursor; sprintf(names[i*DIM*DIM+j*DIM+v], "x[%d,%d,%d]", i, j, v+1); cursor += strlen(names[i*DIM*DIM+j*DIM+v]) + 1; } } } /* Create environment */ error = GRBloadenv(&env, "sudoku.log"); if (error) goto QUIT; /* Create new model */ error = GRBnewmodel(env, &model, "sudoku", DIM*DIM*DIM, NULL, lb, NULL, vtype, names); if (error) goto QUIT; /* Each cell gets a value */ for (i = 0; i < DIM; i++) { for (j = 0; j < DIM; j++) { for (v = 0; v < DIM; v++) { ind[v] = i*DIM*DIM + j*DIM + v; val[v] = 1.0; } error = GRBaddconstr(model, DIM, ind, val, GRB_EQUAL, 1.0, NULL); if (error) goto QUIT; } } /* Each value must appear once in each row */ for (v = 0; v < DIM; v++) { for (j = 0; j < DIM; j++) { for (i = 0; i < DIM; i++) { ind[i] = i*DIM*DIM + j*DIM + v; val[i] = 1.0; } error = GRBaddconstr(model, DIM, ind, val, GRB_EQUAL, 1.0, NULL); if (error) goto QUIT; } } /* Each value must appear once in each column */ for (v = 0; v < DIM; v++) { for (i = 0; i < DIM; i++) { for (j = 0; j < DIM; j++) { ind[j] = i*DIM*DIM + j*DIM + v; val[j] = 1.0; } error = GRBaddconstr(model, DIM, ind, val, GRB_EQUAL, 1.0, NULL); if (error) goto QUIT; } } /* Each value must appear once in each subgrid */ for (v = 0; v < DIM; v++) { for (ig = 0; ig < SUBDIM; ig++) { for (jg = 0; jg < SUBDIM; jg++) { count = 0; for (i = ig*SUBDIM; i < (ig+1)*SUBDIM; i++) { for (j = jg*SUBDIM; j < (jg+1)*SUBDIM; j++) { ind[count] = i*DIM*DIM + j*DIM + v; val[count] = 1.0; count++; } } error = GRBaddconstr(model, DIM, ind, val, GRB_EQUAL, 1.0, NULL); if (error) goto QUIT; } } } /* Optimize model */ error = GRBoptimize(model); if (error) goto QUIT; /* Write model to 'sudoku.lp' */ error = GRBwrite(model, "sudoku.lp"); if (error) goto QUIT; /* Capture solution information */ error = GRBgetintattr(model, GRB_INT_ATTR_STATUS, &optimstatus); if (error) goto QUIT; error = GRBgetdblattr(model, GRB_DBL_ATTR_OBJVAL, &objval); if (error) goto QUIT; printf("\nOptimization complete\n"); if (optimstatus == GRB_OPTIMAL) printf("Optimal objective: %.4e\n", objval); else if (optimstatus == GRB_INF_OR_UNBD) printf("Model is infeasible or unbounded\n"); else printf("Optimization was stopped early\n"); printf("\n"); QUIT: /* Error reporting */ if (error) { printf("ERROR: %s\n", GRBgeterrormsg(env)); exit(1); } fclose(fp); /* Free model */ GRBfreemodel(model); /* Free environment */ GRBfreeenv(env); return 0; }