ortools-clone/examples/python/chemical_balance_sat.py

# 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.

# We are trying to group items in equal sized groups.
# Each item has a color and a value. We want the sum of values of each group to
# be as close to the average as possible.
# Furthermore, if one color is an a group, at least k items with this color must
# be in that group.


from ortools.sat.python import cp_model
import math

# Data

max_quantities = [["N_Total", 1944], ["P2O5", 1166.4], ["K2O", 1822.5],
                  ["CaO", 1458], ["MgO", 486], ["Fe", 9.7], ["B", 2.4]]

chemical_set = [["A", 0, 0, 510, 540, 0, 0, 0], ["B", 110, 0, 0, 0, 160, 0, 0],
                ["C", 61, 149, 384, 0, 30, 1,
                 0.2], ["D", 148, 70, 245, 0, 15, 1,
                        0.2], ["E", 160, 158, 161, 0, 10, 1, 0.2]]

num_products = len(max_quantities)
all_products = range(num_products)

num_sets = len(chemical_set)
all_sets = range(num_sets)

# Model

model = cp_model.CpModel()

# Scale quantities by 100.
max_set = [
    int(
        math.ceil(
            min(max_quantities[q][1] * 1000 / chemical_set[s][q + 1]
                for q in all_products if chemical_set[s][q + 1] != 0)))
    for s in all_sets
]

set_vars = [model.NewIntVar(0, max_set[s], "set_%i" % s) for s in all_sets]

epsilon = model.NewIntVar(0, 10000000, "epsilon")

for p in all_products:
    model.Add(
        sum(int(chemical_set[s][p + 1] * 10) * set_vars[s]
            for s in all_sets) <= int(max_quantities[p][1] * 10000))
    model.Add(
        sum(int(chemical_set[s][p + 1] * 10) * set_vars[s]
            for s in all_sets) >= int(max_quantities[p][1] * 10000) - epsilon)

model.Minimize(epsilon)

# Creates a solver and solves.
solver = cp_model.CpSolver()
status = solver.Solve(model)
print("Status = %s" % solver.StatusName(status))
# The objective value of the solution.
print("Optimal objective value = %f" % (solver.ObjectiveValue() / 10000.0))

for s in all_sets:
    print(
        "  %s = %f" % (chemical_set[s][0], solver.Value(set_vars[s]) / 1000.0),
        end=" ")
    print()
for p in all_products:
    name = max_quantities[p][0]
    max_quantity = max_quantities[p][1]
    quantity = sum(
        solver.Value(set_vars[s]) / 1000.0 * chemical_set[s][p + 1]
        for s in all_sets)
    print("%s: %f out of %f" % (name, quantity, max_quantity))
Bump license date 2022-06-17 08:40:20 +02:00			`# Copyright 2010-2022 Google LLC`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00			`# 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.`

			`# We are trying to group items in equal sized groups.`
			`# Each item has a color and a value. We want the sum of values of each group to`
			`# be as close to the average as possible.`
			`# Furthermore, if one color is an a group, at least k items with this color must`
			`# be in that group.`


			`from ortools.sat.python import cp_model`
			`import math`

			`# Data`

reindent python examples, polish a few of thems 2018-09-06 15:09:32 +02:00			`max_quantities = [["N_Total", 1944], ["P2O5", 1166.4], ["K2O", 1822.5],`
			`["CaO", 1458], ["MgO", 486], ["Fe", 9.7], ["B", 2.4]]`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00
reindent python examples, polish a few of thems 2018-09-06 15:09:32 +02:00			`chemical_set = [["A", 0, 0, 510, 540, 0, 0, 0], ["B", 110, 0, 0, 0, 160, 0, 0],`
Apply yapf on examples/python/*.py 2018-11-28 10:56:33 +01:00			`["C", 61, 149, 384, 0, 30, 1,`
			`0.2], ["D", 148, 70, 245, 0, 15, 1,`
			`0.2], ["E", 160, 158, 161, 0, 10, 1, 0.2]]`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00
			`num_products = len(max_quantities)`
			`all_products = range(num_products)`

			`num_sets = len(chemical_set)`
			`all_sets = range(num_sets)`

			`# Model`

			`model = cp_model.CpModel()`

			`# Scale quantities by 100.`
reindent python examples, polish a few of thems 2018-09-06 15:09:32 +02:00			`max_set = [`
			`int(`
			`math.ceil(`
			`min(max_quantities[q][1] * 1000 / chemical_set[s][q + 1]`
reformat python files as tab length = 4 now 2018-11-11 09:39:59 +01:00			`for q in all_products if chemical_set[s][q + 1] != 0)))`
reindent python examples, polish a few of thems 2018-09-06 15:09:32 +02:00			`for s in all_sets`
			`]`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00
reindent python examples, polish a few of thems 2018-09-06 15:09:32 +02:00			`set_vars = [model.NewIntVar(0, max_set[s], "set_%i" % s) for s in all_sets]`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00
reindent python examples, polish a few of thems 2018-09-06 15:09:32 +02:00			`epsilon = model.NewIntVar(0, 10000000, "epsilon")`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00
			`for p in all_products:`
reformat python files as tab length = 4 now 2018-11-11 09:39:59 +01:00			`model.Add(`
			`sum(int(chemical_set[s][p + 1] * 10) * set_vars[s]`
			`for s in all_sets) <= int(max_quantities[p][1] * 10000))`
			`model.Add(`
			`sum(int(chemical_set[s][p + 1] * 10) * set_vars[s]`
			`for s in all_sets) >= int(max_quantities[p][1] * 10000) - epsilon)`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00
			`model.Minimize(epsilon)`

			`# Creates a solver and solves.`
			`solver = cp_model.CpSolver()`
			`status = solver.Solve(model)`
reindent python examples, polish a few of thems 2018-09-06 15:09:32 +02:00			`print("Status = %s" % solver.StatusName(status))`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00			`# The objective value of the solution.`
reindent python examples, polish a few of thems 2018-09-06 15:09:32 +02:00			`print("Optimal objective value = %f" % (solver.ObjectiveValue() / 10000.0))`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00
			`for s in all_sets:`
reformat python files as tab length = 4 now 2018-11-11 09:39:59 +01:00			`print(`
			`" %s = %f" % (chemical_set[s][0], solver.Value(set_vars[s]) / 1000.0),`
			`end=" ")`
			`print()`
chemical balance problem solved by SAT and LP 2018-08-20 09:09:08 +02:00			`for p in all_products:`
reformat python files as tab length = 4 now 2018-11-11 09:39:59 +01:00			`name = max_quantities[p][0]`
			`max_quantity = max_quantities[p][1]`
			`quantity = sum(`
			`solver.Value(set_vars[s]) / 1000.0 * chemical_set[s][p + 1]`
			`for s in all_sets)`
			`print("%s: %f out of %f" % (name, quantity, max_quantity))`