# Copyright 2010 Hakan Kjellerstrand hakank@gmail.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. """ P-median problem in Google CP Solver. Model and data from the OPL Manual, which describes the problem: ''' The P-Median problem is a well known problem in Operations Research. The problem can be stated very simply, like this: given a set of customers with known amounts of demand, a set of candidate locations for warehouses, and the distance between each pair of customer-warehouse, choose P warehouses to open that minimize the demand-weighted distance of serving all customers from those P warehouses. ''' Compare with the following models: * MiniZinc: http://hakank.org/minizinc/p_median.mzn * Comet: http://hakank.org/comet/p_median.co This model was created by Hakan Kjellerstrand (hakank@gmail.com) Also see my other Google CP Solver models: http://www.hakank.org/google_or_tools/ """ from __future__ import print_function import sys from ortools.constraint_solver import pywrapcp def main(): # Create the solver. solver = pywrapcp.Solver('P-median problem') # # data # p = 2 num_customers = 4 customers = list(range(num_customers)) Albert, Bob, Chris, Daniel = customers num_warehouses = 3 warehouses = list(range(num_warehouses)) Santa_Clara, San_Jose, Berkeley = warehouses demand = [100, 80, 80, 70] distance = [[2, 10, 50], [2, 10, 52], [50, 60, 3], [40, 60, 1]] # # declare variables # open = [solver.IntVar(warehouses, 'open[%i]% % i') for w in warehouses] ship = {} for c in customers: for w in warehouses: ship[c, w] = solver.IntVar(0, 1, 'ship[%i,%i]' % (c, w)) ship_flat = [ship[c, w] for c in customers for w in warehouses] z = solver.IntVar(0, 1000, 'z') # # constraints # z_sum = solver.Sum([ demand[c] * distance[c][w] * ship[c, w] for c in customers for w in warehouses ]) solver.Add(z == z_sum) for c in customers: s = solver.Sum([ship[c, w] for w in warehouses]) solver.Add(s == 1) solver.Add(solver.Sum(open) == p) for c in customers: for w in warehouses: solver.Add(ship[c, w] <= open[w]) # objective objective = solver.Minimize(z, 1) # # solution and search # db = solver.Phase(open + ship_flat, solver.INT_VAR_DEFAULT, solver.INT_VALUE_DEFAULT) solver.NewSearch(db, [objective]) num_solutions = 0 while solver.NextSolution(): num_solutions += 1 print('z:', z.Value()) print('open:', [open[w].Value() for w in warehouses]) for c in customers: for w in warehouses: print(ship[c, w].Value(), end=' ') print() print() print('num_solutions:', num_solutions) print('failures:', solver.Failures()) print('branches:', solver.Branches()) print('WallTime:', solver.WallTime(), 'ms') if __name__ == '__main__': main()