# Copyright 2010-2021 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.
"""Linear programming examples that show how to use the APIs."""

from ortools.linear_solver import pywraplp


def Announce(solver, api_type):
    print('---- Linear programming example with ' + solver + ' (' + api_type +
          ') -----')


def RunLinearExampleNaturalLanguageAPI(optimization_problem_type):
    """Example of simple linear program with natural language API."""
    solver = pywraplp.Solver.CreateSolver(optimization_problem_type)

    if not solver:
        return

    Announce(optimization_problem_type, 'natural language API')

    infinity = solver.infinity()
    # x1, x2 and x3 are continuous non-negative variables.
    x1 = solver.NumVar(0.0, infinity, 'x1')
    x2 = solver.NumVar(0.0, infinity, 'x2')
    x3 = solver.NumVar(0.0, infinity, 'x3')

    solver.Maximize(10 * x1 + 6 * x2 + 4 * x3)
    c0 = solver.Add(10 * x1 + 4 * x2 + 5 * x3 <= 600, 'ConstraintName0')
    c1 = solver.Add(2 * x1 + 2 * x2 + 6 * x3 <= 300)
    sum_of_vars = sum([x1, x2, x3])
    c2 = solver.Add(sum_of_vars <= 100.0, 'OtherConstraintName')

    SolveAndPrint(solver, [x1, x2, x3], [c0, c1, c2])
    # Print a linear expression's solution value.
    print('Sum of vars: %s = %s' % (sum_of_vars, sum_of_vars.solution_value()))


def RunLinearExampleCppStyleAPI(optimization_problem_type):
    """Example of simple linear program with the C++ style API."""
    solver = pywraplp.Solver.CreateSolver(optimization_problem_type)
    if not solver:
        return

    Announce(optimization_problem_type, 'C++ style API')

    infinity = solver.infinity()
    # x1, x2 and x3 are continuous non-negative variables.
    x1 = solver.NumVar(0.0, infinity, 'x1')
    x2 = solver.NumVar(0.0, infinity, 'x2')
    x3 = solver.NumVar(0.0, infinity, 'x3')

    # Maximize 10 * x1 + 6 * x2 + 4 * x3.
    objective = solver.Objective()
    objective.SetCoefficient(x1, 10)
    objective.SetCoefficient(x2, 6)
    objective.SetCoefficient(x3, 4)
    objective.SetMaximization()

    # x1 + x2 + x3 <= 100.
    c0 = solver.Constraint(-infinity, 100.0, 'c0')
    c0.SetCoefficient(x1, 1)
    c0.SetCoefficient(x2, 1)
    c0.SetCoefficient(x3, 1)

    # 10 * x1 + 4 * x2 + 5 * x3 <= 600.
    c1 = solver.Constraint(-infinity, 600.0, 'c1')
    c1.SetCoefficient(x1, 10)
    c1.SetCoefficient(x2, 4)
    c1.SetCoefficient(x3, 5)

    # 2 * x1 + 2 * x2 + 6 * x3 <= 300.
    c2 = solver.Constraint(-infinity, 300.0, 'c2')
    c2.SetCoefficient(x1, 2)
    c2.SetCoefficient(x2, 2)
    c2.SetCoefficient(x3, 6)

    SolveAndPrint(solver, [x1, x2, x3], [c0, c1, c2])


def SolveAndPrint(solver, variable_list, constraint_list):
    """Solve the problem and print the solution."""
    print('Number of variables = %d' % solver.NumVariables())
    print('Number of constraints = %d' % solver.NumConstraints())

    result_status = solver.Solve()

    # The problem has an optimal solution.
    assert result_status == pywraplp.Solver.OPTIMAL

    # The solution looks legit (when using solvers others than
    # GLOP_LINEAR_PROGRAMMING, verifying the solution is highly recommended!).
    assert solver.VerifySolution(1e-7, True)

    print('Problem solved in %f milliseconds' % solver.wall_time())

    # The objective value of the solution.
    print('Optimal objective value = %f' % solver.Objective().Value())

    # The value of each variable in the solution.
    for variable in variable_list:
        print('%s = %f' % (variable.name(), variable.solution_value()))

    print('Advanced usage:')
    print('Problem solved in %d iterations' % solver.iterations())
    for variable in variable_list:
        print('%s: reduced cost = %f' %
              (variable.name(), variable.reduced_cost()))
    activities = solver.ComputeConstraintActivities()
    for i, constraint in enumerate(constraint_list):
        print(('constraint %d: dual value = %f\n'
               '               activity = %f' %
               (i, constraint.dual_value(), activities[constraint.index()])))


def main():
    RunLinearExampleNaturalLanguageAPI('GLOP')
    RunLinearExampleNaturalLanguageAPI('GLPK_LP')
    RunLinearExampleNaturalLanguageAPI('CLP')

    RunLinearExampleCppStyleAPI('GLOP')
    RunLinearExampleCppStyleAPI('GLPK_LP')
    RunLinearExampleCppStyleAPI('CLP')


if __name__ == '__main__':
    main()