ortools-clone/examples/python/shift_scheduling_sat.py

# Copyright 2010-2018 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.
"""Creates a shift scheduling problem and solves it."""

from ortools.sat.python import cp_model

from google.protobuf import text_format
from absl import app
from absl import flags

FLAGS = flags.FLAGS

flags.DEFINE_string('output_proto', '',
                    'Output file to write the cp_model proto to.')
flags.DEFINE_string('params', '', 'Sat solver parameters.')


def negated_bounded_span(works, start, length):
    """Filters an isolated sub-sequence of variables assined to True.

  Extract the span of Boolean variables [start, start + length), negate them,
  and if there is variables to the left/right of this span, surround the span by
  them in non negated form.

  Args:
    works: a list of variables to extract the span from.
    start: the start to the span.
    length: the length of the span.

  Returns:
    a list of variables which conjunction will be false if the sub-list is
    assigned to True, and correctly bounded by variables assigned to False,
    or by the start or end of works.
  """
    sequence = []
    # Left border (start of works, or works[start - 1])
    if start > 0:
        sequence.append(works[start - 1])
    for i in range(length):
        sequence.append(works[start + i].Not())
    # Right border (end of works or works[start + length])
    if start + length < len(works):
        sequence.append(works[start + length])
    return sequence


def add_soft_sequence_constraint(model, works, hard_min, soft_min, min_cost,
                                 soft_max, hard_max, max_cost, prefix):
    """Sequence constraint on true variables with soft and hard bounds.

  This constraint look at every maximal contiguous sequence of variables
  assigned to true. If forbids sequence of length < hard_min or > hard_max.
  Then it creates penalty terms if the length is < soft_min or > soft_max.

  Args:
    model: the sequence constraint is built on this model.
    works: a list of Boolean variables.
    hard_min: any sequence of true variables must have a length of at least
      hard_min.
    soft_min: any sequence should have a length of at least soft_min, or a
      linear penalty on the delta will be added to the objective.
    min_cost: the coefficient of the linear penalty if the length is less than
      soft_min.
    soft_max: any sequence should have a length of at most soft_max, or a linear
      penalty on the delta will be added to the objective.
    hard_max: any sequence of true variables must have a length of at most
      hard_max.
    max_cost: the coefficient of the linear penalty if the length is more than
      soft_max.
    prefix: a base name for penalty literals.

  Returns:
    a tuple (variables_list, coefficient_list) containing the different
    penalties created by the sequence constraint.
  """
    cost_literals = []
    cost_coefficients = []

    # Forbid sequences that are too short.
    for length in range(1, hard_min):
        for start in range(len(works) - length - 1):
            model.AddBoolOr(negated_bounded_span(works, start, length))

    # Penalize sequences that are below the soft limit.
    if min_cost > 0:
        for length in range(hard_min, soft_min):
            for start in range(len(works) - length - 1):
                span = negated_bounded_span(works, start, length)
                name = ': under_span(start=%i, length=%i)' % (start, length)
                lit = model.NewBoolVar(prefix + name)
                span.append(lit)
                model.AddBoolOr(span)
                cost_literals.append(lit)
                # We filter exactly the sequence with a short length.
                # The penalty is proportional to the delta with soft_min.
                cost_coefficients.append(min_cost * (soft_min - length))

    # Penalize sequences that are above the soft limit.
    if max_cost > 0:
        for length in range(soft_max + 1, hard_max + 1):
            for start in range(len(works) - length - 1):
                span = negated_bounded_span(works, start, length)
                name = ': over_span(start=%i, length=%i)' % (start, length)
                lit = model.NewBoolVar(prefix + name)
                span.append(lit)
                model.AddBoolOr(span)
                cost_literals.append(lit)
                # Cost paid is max_cost * excess length.
                cost_coefficients.append(max_cost * (length - soft_max))

    # Just forbid any sequence of true variables with length hard_max + 1
    for start in range(len(works) - hard_max - 1):
        model.AddBoolOr(
            [works[i].Not() for i in range(start, start + hard_max + 1)])
    return cost_literals, cost_coefficients


def add_soft_sum_constraint(model, works, hard_min, soft_min, min_cost,
                            soft_max, hard_max, max_cost, prefix):
    """Sum constraint with soft and hard bounds.

  This constraint counts the variables assigned to true from works.
  If forbids sum < hard_min or > hard_max.
  Then it creates penalty terms if the sum is < soft_min or > soft_max.

  Args:
    model: the sequence constraint is built on this model.
    works: a list of Boolean variables.
    hard_min: any sequence of true variables must have a sum of at least
      hard_min.
    soft_min: any sequence should have a sum of at least soft_min, or a linear
      penalty on the delta will be added to the objective.
    min_cost: the coefficient of the linear penalty if the sum is less than
      soft_min.
    soft_max: any sequence should have a sum of at most soft_max, or a linear
      penalty on the delta will be added to the objective.
    hard_max: any sequence of true variables must have a sum of at most
      hard_max.
    max_cost: the coefficient of the linear penalty if the sum is more than
      soft_max.
    prefix: a base name for penalty variables.

  Returns:
    a tuple (variables_list, coefficient_list) containing the different
    penalties created by the sequence constraint.
  """
    cost_variables = []
    cost_coefficients = []
    sum_var = model.NewIntVar(hard_min, hard_max, '')
    # This adds the hard constraints on the sum.
    model.Add(sum_var == sum(works))

    # Penalize sums below the soft_min target.
    if soft_min > hard_min and min_cost > 0:
        delta = model.NewIntVar(-len(works), len(works), '')
        model.Add(delta == soft_min - sum_var)
        # TODO(user): Compare efficiency with only excess >= soft_min - sum_var.
        excess = model.NewIntVar(0, 7, prefix + ': under_sum')
        model.AddMaxEquality(excess, [delta, 0])
        cost_variables.append(excess)
        cost_coefficients.append(min_cost)

    # Penalize sums above the soft_max target.
    if soft_max < hard_max and max_cost > 0:
        delta = model.NewIntVar(-7, 7, '')
        model.Add(delta == sum_var - soft_max)
        excess = model.NewIntVar(0, 7, prefix + ': over_sum')
        model.AddMaxEquality(excess, [delta, 0])
        cost_variables.append(excess)
        cost_coefficients.append(max_cost)

    return cost_variables, cost_coefficients


def solve_shift_scheduling(params, output_proto):
    """Solves the shift scheduling problem."""
    # Data
    num_employees = 8
    num_weeks = 3
    shifts = ['O', 'M', 'A', 'N']

    # Fixed assignment: (employee, shift, day).
    # This fixes the first 2 days of the schedule.
    fixed_assignments = [
        (0, 0, 0),
        (1, 0, 0),
        (2, 1, 0),
        (3, 1, 0),
        (4, 2, 0),
        (5, 2, 0),
        (6, 2, 3),
        (7, 3, 0),
        (0, 1, 1),
        (1, 1, 1),
        (2, 2, 1),
        (3, 2, 1),
        (4, 2, 1),
        (5, 0, 1),
        (6, 0, 1),
        (7, 3, 1),
    ]

    # Request: (employee, shift, day, weight)
    # A negative weight indicates that the employee desire this assignment.
    requests = [
        # Employee 3 wants the first Saturday off.
        (3, 0, 5, -2),
        # Employee 5 wants a night shift on the second Thursday.
        (5, 3, 10, -2),
        # Employee 2 does not want a night shift on the third Friday.
        (2, 3, 4, 4)
    ]

    # Shift constraints on continuous sequence :
    #     (shift, hard_min, soft_min, min_penalty,
    #             soft_max, hard_max, max_penalty)
    shift_constraints = [
        # One or two consecutive days of rest, this is a hard constraint.
        (0, 1, 1, 0, 2, 2, 0),
        # betweem 2 and 3 consecutive days of night shifts, 1 and 4 are
        # possible but penalized.
        (3, 1, 2, 20, 3, 4, 5),
    ]

    # Weekly sum constraints on shifts days:
    #     (shift, hard_min, soft_min, min_penalty,
    #             soft_max, hard_max, max_penalty)
    weekly_sum_constraints = [
        # Constraints on rests per week.
        (0, 1, 2, 7, 2, 3, 4),
        # At least 1 night shift per week (penalized). At most 4 (hard).
        (3, 0, 1, 3, 4, 4, 0),
    ]

    # Penalized transitions:
    #     (previous_shift, next_shift, penalty (0 means forbidden))
    penalized_transitions = [
        # Afternoon to night has a penalty of 4.
        (2, 3, 4),
        # Night to morning is forbidden.
        (3, 1, 0),
    ]

    # daily demands for work shifts (morning, afternon, night) for each day
    # of the week starting on Monday.
    weekly_cover_demands = [
        (2, 3, 1),  # Monday
        (2, 3, 1),  # Tuesday
        (2, 2, 2),  # Wednesday
        (2, 3, 1),  # Thursday
        (2, 2, 2),  # Friday
        (1, 2, 3),  # Saturday
        (1, 3, 1),  # Sunday
    ]

    # Penalty for exceeding the cover constraint per shift type.
    excess_cover_penalties = (2, 2, 5)

    num_days = num_weeks * 7
    num_shifts = len(shifts)

    model = cp_model.CpModel()

    work = {}
    for e in range(num_employees):
        for s in range(num_shifts):
            for d in range(num_days):
                work[e, s, d] = model.NewBoolVar('work%i_%i_%i' % (e, s, d))

    # Linear terms of the objective in a minimization context.
    obj_int_vars = []
    obj_int_coeffs = []
    obj_bool_vars = []
    obj_bool_coeffs = []

    # Exactly one shift per day.
    for e in range(num_employees):
        for d in range(num_days):
            model.Add(sum(work[e, s, d] for s in range(num_shifts)) == 1)

    # Fixed assignments.
    for e, s, d in fixed_assignments:
        model.Add(work[e, s, d] == 1)

    # Employee requests
    for e, s, d, w in requests:
        obj_bool_vars.append(work[e, s, d])
        obj_bool_coeffs.append(w)

    # Shift constraints
    for ct in shift_constraints:
        shift, hard_min, soft_min, min_cost, soft_max, hard_max, max_cost = ct
        for e in range(num_employees):
            works = [work[e, shift, d] for d in range(num_days)]
            variables, coeffs = add_soft_sequence_constraint(
                model, works, hard_min, soft_min, min_cost, soft_max, hard_max,
                max_cost,
                'shift_constraint(employee %i, shift %i)' % (e, shift))
            obj_bool_vars.extend(variables)
            obj_bool_coeffs.extend(coeffs)

    # Weekly sum constraints
    for ct in weekly_sum_constraints:
        shift, hard_min, soft_min, min_cost, soft_max, hard_max, max_cost = ct
        for e in range(num_employees):
            for w in range(num_weeks):
                works = [work[e, shift, d + w * 7] for d in range(7)]
                variables, coeffs = add_soft_sum_constraint(
                    model, works, hard_min, soft_min, min_cost, soft_max,
                    hard_max, max_cost,
                    'weekly_sum_constraint(employee %i, shift %i, week %i)' %
                    (e, shift, w))
                obj_int_vars.extend(variables)
                obj_int_coeffs.extend(coeffs)

    # Penalized transitions
    for previous_shift, next_shift, cost in penalized_transitions:
        for e in range(num_employees):
            for d in range(num_days - 1):
                transition = [
                    work[e, previous_shift, d].Not(), work[e, next_shift,
                                                           d + 1].Not()
                ]
                if cost == 0:
                    model.AddBoolOr(transition)
                else:
                    trans_var = model.NewBoolVar(
                        'transition (employee=%i, day=%i)' % (e, d))
                    transition.append(trans_var)
                    model.AddBoolOr(transition)
                    obj_bool_vars.append(trans_var)
                    obj_bool_coeffs.append(cost)

    # Cover constraints
    for s in range(1, num_shifts):
        for w in range(num_weeks):
            for d in range(7):
                works = [work[e, s, w * 7 + d] for e in range(num_employees)]
                # Ignore Off shift.
                min_demand = weekly_cover_demands[d][s - 1]
                worked = model.NewIntVar(min_demand, num_employees, '')
                model.Add(worked == sum(works))
                over_penalty = excess_cover_penalties[s - 1]
                if over_penalty > 0:
                    name = 'excess_demand(shift=%i, week=%i, day=%i)' % (s, w,
                                                                         d)
                    excess = model.NewIntVar(0, num_employees - min_demand,
                                             name)
                    model.Add(excess == worked - min_demand)
                    obj_int_vars.append(excess)
                    obj_int_coeffs.append(over_penalty)

    # Objective
    model.Minimize(
        sum(obj_bool_vars[i] * obj_bool_coeffs[i]
            for i in range(len(obj_bool_vars))) +
        sum(obj_int_vars[i] * obj_int_coeffs[i]
            for i in range(len(obj_int_vars))))

    if output_proto:
        print('Writing proto to %s' % output_proto)
        with open(output_proto, 'w') as text_file:
            text_file.write(str(model))

    # Solve the model.
    solver = cp_model.CpSolver()
    if params:
        text_format.Parse(params, solver.parameters)
    else:
        text_format.Parse(r'max_time_in_seconds:10.0', solver.parameters)
    solution_printer = cp_model.ObjectiveSolutionPrinter()
    status = solver.SolveWithSolutionCallback(model, solution_printer)

    # Print solution.
    if status == cp_model.OPTIMAL or status == cp_model.FEASIBLE:
        print()
        header = '          '
        for w in range(num_weeks):
            header += 'M T W T F S S '
        print(header)
        for e in range(num_employees):
            schedule = ''
            for d in range(num_days):
                for s in range(num_shifts):
                    if solver.BooleanValue(work[e, s, d]):
                        schedule += shifts[s] + ' '
            print('worker %i: %s' % (e, schedule))
        print()
        print('Penalties:')
        for i, var in enumerate(obj_bool_vars):
            if solver.BooleanValue(var):
                penalty = obj_bool_coeffs[i]
                if penalty > 0:
                    print('  %s violated, penalty=%i' % (var.Name(), penalty))
                else:
                    print('  %s fulfilled, gain=%i' % (var.Name(), -penalty))

        for i, var in enumerate(obj_int_vars):
            if solver.Value(var) > 0:
                print('  %s violated by %i, linear penalty=%i' %
                      (var.Name(), solver.Value(var), obj_int_coeffs[i]))

    print()
    print('Statistics')
    print('  - status          : %s' % solver.StatusName(status))
    print('  - conflicts       : %i' % solver.NumConflicts())
    print('  - branches        : %i' % solver.NumBranches())
    print('  - wall time       : %f s' % solver.WallTime())


def main(_):
    solve_shift_scheduling(FLAGS.params, FLAGS.output_proto)


if __name__ == '__main__':
    app.run(main)