ortools-clone/examples/python/set_covering.py

# Copyright 2010 Hakan Kjellerstrand hakank@bonetmail.com
#
# 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.

"""

  Set covering in Google CP Solver.

  Placing of firestations, from Winston 'Operations Research', page 486.

  Compare with the following models:
  * MiniZinc: http://www.hakank.org/minizinc/set_covering.mzn
  * ECLiPSe : http://www.hakank.org/eclipse/set_covering.ecl
  * Comet   : http://www.hakank.org/comet/set_covering.co
  * Gecode  : http://www.hakank.org/gecode/set_covering.cpp
  * SICStus : http://www.hakank.org/sicstus/set_covering.pl


  This model was created by Hakan Kjellerstrand (hakank@bonetmail.com)
  Also see my other Google CP Solver models: http://www.hakank.org/google_or_tools/

"""

from ortools.constraint_solver import pywrapcp

def main(unused_argv):

    # Create the solver.
    solver = pywrapcp.Solver('Set covering')

    #
    # data
    #
    min_distance = 15
    num_cities = 6

    distance = [
        [ 0,10,20,30,30,20],
        [10, 0,25,35,20,10],
        [20,25, 0,15,30,20],
        [30,35,15, 0,15,25],
        [30,20,30,15, 0,14],
        [20,10,20,25,14, 0]
        ]

    #
    # declare variables
    #
    x = [solver.IntVar(0,1, 'x[%i]' % i) for i in range(num_cities)]

    #
    # constraints
    #

    # objective to minimize
    z = solver.Sum(x)

    # ensure that all cities are covered
    for i in range(num_cities):
        b = [x[j] for j in range(num_cities) if distance[i][j] <= min_distance]
        solver.Add(solver.SumGreaterOrEqual(b, 1))

    objective = solver.Minimize(z, 1)

    #
    # solution and search
    #
    solution = solver.Assignment()
    solution.Add(x)
    solution.AddObjective(z)

    collector = solver.LastSolutionCollector(solution)
    solver.Solve(solver.Phase(x + [z],
                              solver.INT_VAR_DEFAULT,
                              solver.INT_VALUE_DEFAULT),
                 [collector, objective])

    print "z:", collector.ObjectiveValue(0)
    print "x:", [collector.Value(0, x[i]) for i in range(num_cities)]

    print "failures:", solver.Failures()
    print "branches:", solver.Branches()
    print "WallTime:", solver.WallTime()


if __name__ == '__main__':
    main("cp sample")