ortools-clone/ortools/linear_solver/samples/assignment_groups_mip.py

#!/usr/bin/env python3
# Copyright 2010-2022 Google LLC
# 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.

# [START program]
"""Solve assignment problem for given group of workers."""
# [START import]
from ortools.linear_solver import pywraplp
# [END import]


def main():
    # Data
    # [START data]
    costs = [
        [90, 76, 75, 70, 50, 74],
        [35, 85, 55, 65, 48, 101],
        [125, 95, 90, 105, 59, 120],
        [45, 110, 95, 115, 104, 83],
        [60, 105, 80, 75, 59, 62],
        [45, 65, 110, 95, 47, 31],
        [38, 51, 107, 41, 69, 99],
        [47, 85, 57, 71, 92, 77],
        [39, 63, 97, 49, 118, 56],
        [47, 101, 71, 60, 88, 109],
        [17, 39, 103, 64, 61, 92],
        [101, 45, 83, 59, 92, 27],
    ]
    num_workers = len(costs)
    num_tasks = len(costs[0])
    # [END data]

    # Allowed groups of workers:
    # [START allowed_groups]
    group1 = [  # Subgroups of workers 0 - 3
        [2, 3],
        [1, 3],
        [1, 2],
        [0, 1],
        [0, 2],
    ]

    group2 = [  # Subgroups of workers 4 - 7
        [6, 7],
        [5, 7],
        [5, 6],
        [4, 5],
        [4, 7],
    ]

    group3 = [  # Subgroups of workers 8 - 11
        [10, 11],
        [9, 11],
        [9, 10],
        [8, 10],
        [8, 11],
    ]
    # [END allowed_groups]

    # Solver.
    # [START solver]
    # Create the mip solver with the SCIP backend.
    solver = pywraplp.Solver.CreateSolver('SCIP')
    if not solver:
        return
    # [END solver]

    # Variables
    # [START variables]
    # x[worker, task] is an array of 0-1 variables, which will be 1
    # if the worker is assigned to the task.
    x = {}
    for worker in range(num_workers):
        for task in range(num_tasks):
            x[worker, task] = solver.BoolVar(f'x[{worker},{task}]')
    # [END variables]

    # Constraints
    # [START constraints]
    # The total size of the tasks each worker takes on is at most total_size_max.
    for worker in range(num_workers):
        solver.Add(
            solver.Sum([x[worker, task] for task in range(num_tasks)]) <= 1)

    # Each task is assigned to exactly one worker.
    for task in range(num_tasks):
        solver.Add(
            solver.Sum([x[worker, task] for worker in range(num_workers)]) == 1)
    # [END constraints]

    # [START assignments]
    # Create variables for each worker, indicating whether they work on some task.
    work = {}
    for worker in range(num_workers):
        work[worker] = solver.BoolVar(f'work[{worker}]')

    for worker in range(num_workers):
        solver.Add(work[worker] == solver.Sum(
            [x[worker, task] for task in range(num_tasks)]))

    # Group1
    constraint_g1 = solver.Constraint(1, 1)
    for i in range(len(group1)):
        # a*b can be transformed into 0 <= a + b - 2*p <= 1 with p in [0,1]
        # p is True if a AND b, False otherwise
        constraint = solver.Constraint(0, 1)
        constraint.SetCoefficient(work[group1[i][0]], 1)
        constraint.SetCoefficient(work[group1[i][1]], 1)
        p = solver.BoolVar(f'g1_p{i}')
        constraint.SetCoefficient(p, -2)

        constraint_g1.SetCoefficient(p, 1)

    # Group2
    constraint_g2 = solver.Constraint(1, 1)
    for i in range(len(group2)):
        # a*b can be transformed into 0 <= a + b - 2*p <= 1 with p in [0,1]
        # p is True if a AND b, False otherwise
        constraint = solver.Constraint(0, 1)
        constraint.SetCoefficient(work[group2[i][0]], 1)
        constraint.SetCoefficient(work[group2[i][1]], 1)
        p = solver.BoolVar(f'g2_p{i}')
        constraint.SetCoefficient(p, -2)

        constraint_g2.SetCoefficient(p, 1)

    # Group3
    constraint_g3 = solver.Constraint(1, 1)
    for i in range(len(group3)):
        # a*b can be transformed into 0 <= a + b - 2*p <= 1 with p in [0,1]
        # p is True if a AND b, False otherwise
        constraint = solver.Constraint(0, 1)
        constraint.SetCoefficient(work[group3[i][0]], 1)
        constraint.SetCoefficient(work[group3[i][1]], 1)
        p = solver.BoolVar(f'g3_p{i}')
        constraint.SetCoefficient(p, -2)

        constraint_g3.SetCoefficient(p, 1)
    # [END assignments]

    # Objective
    # [START objective]
    objective_terms = []
    for worker in range(num_workers):
        for task in range(num_tasks):
            objective_terms.append(costs[worker][task] * x[worker, task])
    solver.Minimize(solver.Sum(objective_terms))
    # [END objective]

    # Solve
    # [START solve]
    status = solver.Solve()
    # [END solve]

    # Print solution.
    # [START print_solution]
    if status == pywraplp.Solver.OPTIMAL or status == pywraplp.Solver.FEASIBLE:
        print(f'Total cost = {solver.Objective().Value()}\n')
        for worker in range(num_workers):
            for task in range(num_tasks):
                if x[worker, task].solution_value() > 0.5:
                    print(f'Worker {worker} assigned to task {task}.' +
                          f' Cost: {costs[worker][task]}')
    else:
        print('No solution found.')
    # [END print_solution]


if __name__ == '__main__':
    main()
# [END program]