In diesem Abschnitt wird gezeigt, wie Sie das Rucksackproblem für mehrere Rucksäcke lösen. mit dem MIP- und dem CP-SAT-Löser. In diesem Fall werden die Container häufig als bins bezeichnet und nicht als Rucksäcke.
Das nächste Beispiel zeigt, wie Sie die optimale Methode finden, Artikel in fünf Container zu verpacken.
Beispiel
Wie im vorherigen Beispiel beginnen Sie mit einer Sammlung von Elementen mit unterschiedlicher Gewichtung und Werten. Das Problem ist, eine der Artikel werden in fünf Behälter aufgeteilt, die jeweils eine maximale Kapazität von 100 Behältern haben. damit der gesamte verpackte Wert ein Maximum ist.
In den folgenden Abschnitten werden Abschnitte von Programmen vorgestellt, die dieses Problem lösen. Die vollständigen Programme finden Sie unter Programme abschließen.
MIP-Lösung
In den folgenden Abschnitten wird beschrieben, wie Sie das Problem mithilfe des MPResolver-Wrapper.
Bibliotheken importieren
Mit dem folgenden Code werden die erforderlichen Bibliotheken importiert.
Python
from ortools.linear_solver import pywraplp
C++
#include <iostream> #include <memory> #include <numeric> #include <vector> #include "absl/strings/str_format.h" #include "ortools/linear_solver/linear_expr.h" #include "ortools/linear_solver/linear_solver.h"
Java
import com.google.ortools.Loader; import com.google.ortools.linearsolver.MPConstraint; import com.google.ortools.linearsolver.MPObjective; import com.google.ortools.linearsolver.MPSolver; import com.google.ortools.linearsolver.MPVariable; import java.util.stream.IntStream;
C#
using System; using System.Collections.Generic; using System.Linq; using Google.OrTools.LinearSolver;
Daten erstellen
Mit dem folgenden Code werden die Daten für das Problem erstellt.
Python
data = {} data["weights"] = [48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36] data["values"] = [10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25] assert len(data["weights"]) == len(data["values"]) data["num_items"] = len(data["weights"]) data["all_items"] = range(data["num_items"]) data["bin_capacities"] = [100, 100, 100, 100, 100] data["num_bins"] = len(data["bin_capacities"]) data["all_bins"] = range(data["num_bins"])
C++
const std::vector<int> weights = { {48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36}}; const std::vector<int> values = { {10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25}}; const int num_items = weights.size(); std::vector<int> all_items(num_items); std::iota(all_items.begin(), all_items.end(), 0); const std::vector<int> bin_capacities = {{100, 100, 100, 100, 100}}; const int num_bins = bin_capacities.size(); std::vector<int> all_bins(num_bins); std::iota(all_bins.begin(), all_bins.end(), 0);
Java
final double[] weights = {48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36};
final double[] values = {10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25};
final int numItems = weights.length;
final int[] allItems = IntStream.range(0, numItems).toArray();
final double[] binCapacities = {100, 100, 100, 100, 100};
final int numBins = binCapacities.length;
final int[] allBins = IntStream.range(0, numBins).toArray();C#
double[] Weights = { 48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36 };
double[] Values = { 10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25 };
int NumItems = Weights.Length;
int[] allItems = Enumerable.Range(0, NumItems).ToArray();
double[] BinCapacities = { 100, 100, 100, 100, 100 };
int NumBins = BinCapacities.Length;
int[] allBins = Enumerable.Range(0, NumBins).ToArray();Die Daten umfassen Folgendes:
weights: Ein Vektor, der die Gewichtung der Elemente enthält.values: Ein Vektor mit den Werten der Elemente.capacities: Ein Vektor, der die Kapazitäten der Klassen enthält.
In diesem Beispiel haben alle Container die gleiche Kapazität. Das muss aber nicht zutreffen. im Allgemeinen.
MIP-Löser deklarieren
Mit dem folgenden Code wird der MIP-Löser deklariert.
Python
solver = pywraplp.Solver.CreateSolver("SCIP") if solver is None: print("SCIP solver unavailable.") return
C++
std::unique_ptr<MPSolver> solver(MPSolver::CreateSolver("SCIP")); if (!solver) { LOG(WARNING) << "SCIP solver unavailable."; return; }
Java
// Create the linear solver with the SCIP backend. MPSolver solver = MPSolver.createSolver("SCIP"); if (solver == null) { System.out.println("Could not create solver SCIP"); return; }
C#
// Create the linear solver with the SCIP backend. Solver solver = Solver.CreateSolver("SCIP"); if (solver is null) { return; }
Variablen erstellen
Mit dem folgenden Code werden die Variablen für das Problem erstellt.
Python
# x[i, b] = 1 if item i is packed in bin b. x = {} for i in data["all_items"]: for b in data["all_bins"]: x[i, b] = solver.BoolVar(f"x_{i}_{b}")
C++
// x[i][b] = 1 if item i is packed in bin b. std::vector<std::vector<const MPVariable*>> x( num_items, std::vector<const MPVariable*>(num_bins)); for (int i : all_items) { for (int b : all_bins) { x[i][b] = solver->MakeBoolVar(absl::StrFormat("x_%d_%d", i, b)); } }
Java
MPVariable[][] x = new MPVariable[numItems][numBins]; for (int i : allItems) { for (int b : allBins) { x[i][b] = solver.makeBoolVar("x_" + i + "_" + b); } }
C#
Variable[,] x = new Variable[NumItems, NumBins];
foreach (int i in allItems)
{
foreach (int b in allBins)
{
x[i, b] = solver.MakeBoolVar($"x_{i}_{b}");
}
}Jede x[(i, j)] ist eine Variable von 0–1, wobei i ein Element und j ein Container ist. In
Lösung: x[(i, j)] ist 1, wenn das Element i in Container j platziert wird, und 0
sonst.
Einschränkungen definieren
Der folgende Code definiert die Einschränkungen für das Problem:
Python
# Each item is assigned to at most one bin. for i in data["all_items"]: solver.Add(sum(x[i, b] for b in data["all_bins"]) <= 1) # The amount packed in each bin cannot exceed its capacity. for b in data["all_bins"]: solver.Add( sum(x[i, b] * data["weights"][i] for i in data["all_items"]) <= data["bin_capacities"][b] )
C++
// Each item is assigned to at most one bin. for (int i : all_items) { LinearExpr sum; for (int b : all_bins) { sum += x[i][b]; } solver->MakeRowConstraint(sum <= 1.0); } // The amount packed in each bin cannot exceed its capacity. for (int b : all_bins) { LinearExpr bin_weight; for (int i : all_items) { bin_weight += LinearExpr(x[i][b]) * weights[i]; } solver->MakeRowConstraint(bin_weight <= bin_capacities[b]); }
Java
// Each item is assigned to at most one bin. for (int i : allItems) { MPConstraint constraint = solver.makeConstraint(0, 1, ""); for (int b : allBins) { constraint.setCoefficient(x[i][b], 1); } } // The amount packed in each bin cannot exceed its capacity. for (int b : allBins) { MPConstraint constraint = solver.makeConstraint(0, binCapacities[b], ""); for (int i : allItems) { constraint.setCoefficient(x[i][b], weights[i]); } }
C#
// Each item is assigned to at most one bin. foreach (int i in allItems) { Constraint constraint = solver.MakeConstraint(0, 1, ""); foreach (int b in allBins) { constraint.SetCoefficient(x[i, b], 1); } } // The amount packed in each bin cannot exceed its capacity. foreach (int b in allBins) { Constraint constraint = solver.MakeConstraint(0, BinCapacities[b], ""); foreach (int i in allItems) { constraint.SetCoefficient(x[i, b], Weights[i]); } }
Es gelten die folgenden Einschränkungen:
- Jedes Element kann in höchstens einem Container platziert werden. Diese Einschränkung wird festgelegt von
Die Summe von
x[i, j]in allen Klassenjmuss kleiner oder gleich sein auf 1 gesetzt. - Das Gesamtgewicht in jedem Behälter darf seine Kapazität nicht überschreiten. Dieses
Die Beschränkung wird festgelegt, indem die Summe der Gewichtungen der im Container platzierten Elemente verlangt wird
jmuss kleiner oder gleich der Kapazität des Containers sein.
Ziel definieren
Der folgende Code definiert die Zielfunktion für das Problem, also die Funktion Gesamtwert der verpackten Artikel.
Python
# Maximize total value of packed items. objective = solver.Objective() for i in data["all_items"]: for b in data["all_bins"]: objective.SetCoefficient(x[i, b], data["values"][i]) objective.SetMaximization()
C++
// Maximize total value of packed items. MPObjective* const objective = solver->MutableObjective(); LinearExpr objective_value; for (int i : all_items) { for (int b : all_bins) { objective_value += LinearExpr(x[i][b]) * values[i]; } } objective->MaximizeLinearExpr(objective_value);
Java
// Maximize total value of packed items. MPObjective objective = solver.objective(); for (int i : allItems) { for (int b : allBins) { objective.setCoefficient(x[i][b], values[i]); } } objective.setMaximization();
C#
Objective objective = solver.Objective(); foreach (int i in allItems) { foreach (int b in allBins) { objective.SetCoefficient(x[i, b], Values[i]); } } objective.SetMaximization();
x[i, j] * data['values'][i] fügt den Wert des Elements i zum
wenn das Element in Container j platziert wird. Wenn i nicht in einem Container platziert wird, ist seine
der Wert nicht zum Ziel beiträgt.
Solver aufrufen
Der folgende Code ruft den Solver auf.
Python
print(f"Solving with {solver.SolverVersion()}")
status = solver.Solve()C++
const MPSolver::ResultStatus result_status = solver->Solve();
Java
final MPSolver.ResultStatus status = solver.solve();
C#
Solver.ResultStatus resultStatus = solver.Solve();
Lösung drucken
Der folgende Code gibt die Lösung für das Problem aus.
Python
if status == pywraplp.Solver.OPTIMAL: print(f"Total packed value: {objective.Value()}") total_weight = 0 for b in data["all_bins"]: print(f"Bin {b}") bin_weight = 0 bin_value = 0 for i in data["all_items"]: if x[i, b].solution_value() > 0: print( f"Item {i} weight: {data['weights'][i]} value:" f" {data['values'][i]}" ) bin_weight += data["weights"][i] bin_value += data["values"][i] print(f"Packed bin weight: {bin_weight}") print(f"Packed bin value: {bin_value}\n") total_weight += bin_weight print(f"Total packed weight: {total_weight}") else: print("The problem does not have an optimal solution.")
C++
if (result_status == MPSolver::OPTIMAL) { LOG(INFO) << "Total packed value: " << objective->Value(); double total_weight = 0.0; for (int b : all_bins) { LOG(INFO) << "Bin " << b; double bin_weight = 0.0; double bin_value = 0.0; for (int i : all_items) { if (x[i][b]->solution_value() > 0) { LOG(INFO) << "Item " << i << " weight: " << weights[i] << " value: " << values[i]; bin_weight += weights[i]; bin_value += values[i]; } } LOG(INFO) << "Packed bin weight: " << bin_weight; LOG(INFO) << "Packed bin value: " << bin_value; total_weight += bin_weight; } LOG(INFO) << "Total packed weight: " << total_weight; } else { LOG(INFO) << "The problem does not have an optimal solution."; }
Java
// Check that the problem has an optimal solution. if (status == MPSolver.ResultStatus.OPTIMAL) { System.out.println("Total packed value: " + objective.value()); double totalWeight = 0; for (int b : allBins) { double binWeight = 0; double binValue = 0; System.out.println("Bin " + b); for (int i : allItems) { if (x[i][b].solutionValue() == 1) { System.out.println("Item " + i + " weight: " + weights[i] + " value: " + values[i]); binWeight += weights[i]; binValue += values[i]; } } System.out.println("Packed bin weight: " + binWeight); System.out.println("Packed bin value: " + binValue); totalWeight += binWeight; } System.out.println("Total packed weight: " + totalWeight); } else { System.err.println("The problem does not have an optimal solution."); }
C#
// Check that the problem has an optimal solution. if (resultStatus == Solver.ResultStatus.OPTIMAL) { Console.WriteLine($"Total packed value: {solver.Objective().Value()}"); double TotalWeight = 0.0; foreach (int b in allBins) { double BinWeight = 0.0; double BinValue = 0.0; Console.WriteLine("Bin " + b); foreach (int i in allItems) { if (x[i, b].SolutionValue() == 1) { Console.WriteLine($"Item {i} weight: {Weights[i]} values: {Values[i]}"); BinWeight += Weights[i]; BinValue += Values[i]; } } Console.WriteLine("Packed bin weight: " + BinWeight); Console.WriteLine("Packed bin value: " + BinValue); TotalWeight += BinWeight; } Console.WriteLine("Total packed weight: " + TotalWeight); } else { Console.WriteLine("The problem does not have an optimal solution!"); }
Der Code zeigt für jeden Container die in diesem Container platzierten Elemente sowie die Gesamtwert und Gewichtung. Der Code zeigt auch den Gesamtwert und das Gewicht der verpackten Artikel.
Wenn Sie das Programm ausführen, wird die folgende Ausgabe angezeigt.
Total packed value: 395.0 Bin 0 Item 3 - weight: 36 value: 50 Item 13 - weight: 36 value: 30 Packed bin weight: 72 Packed bin value: 80 Bin 1 Item 5 - weight: 48 value: 30 Item 7 - weight: 42 value: 40 Packed bin weight: 90 Packed bin value: 70 Bin 2 Item 1 - weight: 30 value: 30 Item 10 - weight: 30 value: 45 Item 14 - weight: 36 value: 25 Packed bin weight: 96 Packed bin value: 100 Bin 3 Item 2 - weight: 42 value: 25 Item 12 - weight: 42 value: 20 Packed bin weight: 84 Packed bin value: 45 Bin 4 Item 4 - weight: 36 value: 35 Item 8 - weight: 36 value: 30 Item 9 - weight: 24 value: 35 Packed bin weight: 96 Packed bin value: 100 Total packed weight: 438
Programme abschließen
Die vollständigen Programme für mehrere Rucksäcke sind unten aufgeführt.
Python
"""Solve a multiple knapsack problem using a MIP solver.""" from ortools.linear_solver import pywraplp def main(): data = {} data["weights"] = [48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36] data["values"] = [10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25] assert len(data["weights"]) == len(data["values"]) data["num_items"] = len(data["weights"]) data["all_items"] = range(data["num_items"]) data["bin_capacities"] = [100, 100, 100, 100, 100] data["num_bins"] = len(data["bin_capacities"]) data["all_bins"] = range(data["num_bins"]) # Create the mip solver with the SCIP backend. solver = pywraplp.Solver.CreateSolver("SCIP") if solver is None: print("SCIP solver unavailable.") return # Variables. # x[i, b] = 1 if item i is packed in bin b. x = {} for i in data["all_items"]: for b in data["all_bins"]: x[i, b] = solver.BoolVar(f"x_{i}_{b}") # Constraints. # Each item is assigned to at most one bin. for i in data["all_items"]: solver.Add(sum(x[i, b] for b in data["all_bins"]) <= 1) # The amount packed in each bin cannot exceed its capacity. for b in data["all_bins"]: solver.Add( sum(x[i, b] * data["weights"][i] for i in data["all_items"]) <= data["bin_capacities"][b] ) # Objective. # Maximize total value of packed items. objective = solver.Objective() for i in data["all_items"]: for b in data["all_bins"]: objective.SetCoefficient(x[i, b], data["values"][i]) objective.SetMaximization() print(f"Solving with {solver.SolverVersion()}") status = solver.Solve() if status == pywraplp.Solver.OPTIMAL: print(f"Total packed value: {objective.Value()}") total_weight = 0 for b in data["all_bins"]: print(f"Bin {b}") bin_weight = 0 bin_value = 0 for i in data["all_items"]: if x[i, b].solution_value() > 0: print( f"Item {i} weight: {data['weights'][i]} value:" f" {data['values'][i]}" ) bin_weight += data["weights"][i] bin_value += data["values"][i] print(f"Packed bin weight: {bin_weight}") print(f"Packed bin value: {bin_value}\n") total_weight += bin_weight print(f"Total packed weight: {total_weight}") else: print("The problem does not have an optimal solution.") if __name__ == "__main__": main()
C++
// Solve a multiple knapsack problem using a MIP solver. #include <iostream> #include <memory> #include <numeric> #include <vector> #include "absl/strings/str_format.h" #include "ortools/linear_solver/linear_expr.h" #include "ortools/linear_solver/linear_solver.h" namespace operations_research { void MultipleKnapsackMip() { const std::vector<int> weights = { {48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36}}; const std::vector<int> values = { {10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25}}; const int num_items = weights.size(); std::vector<int> all_items(num_items); std::iota(all_items.begin(), all_items.end(), 0); const std::vector<int> bin_capacities = {{100, 100, 100, 100, 100}}; const int num_bins = bin_capacities.size(); std::vector<int> all_bins(num_bins); std::iota(all_bins.begin(), all_bins.end(), 0); // Create the mip solver with the SCIP backend. std::unique_ptr<MPSolver> solver(MPSolver::CreateSolver("SCIP")); if (!solver) { LOG(WARNING) << "SCIP solver unavailable."; return; } // Variables. // x[i][b] = 1 if item i is packed in bin b. std::vector<std::vector<const MPVariable*>> x( num_items, std::vector<const MPVariable*>(num_bins)); for (int i : all_items) { for (int b : all_bins) { x[i][b] = solver->MakeBoolVar(absl::StrFormat("x_%d_%d", i, b)); } } // Constraints. // Each item is assigned to at most one bin. for (int i : all_items) { LinearExpr sum; for (int b : all_bins) { sum += x[i][b]; } solver->MakeRowConstraint(sum <= 1.0); } // The amount packed in each bin cannot exceed its capacity. for (int b : all_bins) { LinearExpr bin_weight; for (int i : all_items) { bin_weight += LinearExpr(x[i][b]) * weights[i]; } solver->MakeRowConstraint(bin_weight <= bin_capacities[b]); } // Objective. // Maximize total value of packed items. MPObjective* const objective = solver->MutableObjective(); LinearExpr objective_value; for (int i : all_items) { for (int b : all_bins) { objective_value += LinearExpr(x[i][b]) * values[i]; } } objective->MaximizeLinearExpr(objective_value); const MPSolver::ResultStatus result_status = solver->Solve(); if (result_status == MPSolver::OPTIMAL) { LOG(INFO) << "Total packed value: " << objective->Value(); double total_weight = 0.0; for (int b : all_bins) { LOG(INFO) << "Bin " << b; double bin_weight = 0.0; double bin_value = 0.0; for (int i : all_items) { if (x[i][b]->solution_value() > 0) { LOG(INFO) << "Item " << i << " weight: " << weights[i] << " value: " << values[i]; bin_weight += weights[i]; bin_value += values[i]; } } LOG(INFO) << "Packed bin weight: " << bin_weight; LOG(INFO) << "Packed bin value: " << bin_value; total_weight += bin_weight; } LOG(INFO) << "Total packed weight: " << total_weight; } else { LOG(INFO) << "The problem does not have an optimal solution."; } } } // namespace operations_research int main(int argc, char** argv) { operations_research::MultipleKnapsackMip(); return EXIT_SUCCESS; }
Java
// Solve a multiple knapsack problem using a MIP solver. package com.google.ortools.linearsolver.samples; import com.google.ortools.Loader; import com.google.ortools.linearsolver.MPConstraint; import com.google.ortools.linearsolver.MPObjective; import com.google.ortools.linearsolver.MPSolver; import com.google.ortools.linearsolver.MPVariable; import java.util.stream.IntStream; /** Multiple knapsack problem. */ public class MultipleKnapsackMip { public static void main(String[] args) { Loader.loadNativeLibraries(); // Instantiate the data problem. final double[] weights = {48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36}; final double[] values = {10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25}; final int numItems = weights.length; final int[] allItems = IntStream.range(0, numItems).toArray(); final double[] binCapacities = {100, 100, 100, 100, 100}; final int numBins = binCapacities.length; final int[] allBins = IntStream.range(0, numBins).toArray(); // Create the linear solver with the SCIP backend. MPSolver solver = MPSolver.createSolver("SCIP"); if (solver == null) { System.out.println("Could not create solver SCIP"); return; } // Variables. MPVariable[][] x = new MPVariable[numItems][numBins]; for (int i : allItems) { for (int b : allBins) { x[i][b] = solver.makeBoolVar("x_" + i + "_" + b); } } // Constraints. // Each item is assigned to at most one bin. for (int i : allItems) { MPConstraint constraint = solver.makeConstraint(0, 1, ""); for (int b : allBins) { constraint.setCoefficient(x[i][b], 1); } } // The amount packed in each bin cannot exceed its capacity. for (int b : allBins) { MPConstraint constraint = solver.makeConstraint(0, binCapacities[b], ""); for (int i : allItems) { constraint.setCoefficient(x[i][b], weights[i]); } } // Objective. // Maximize total value of packed items. MPObjective objective = solver.objective(); for (int i : allItems) { for (int b : allBins) { objective.setCoefficient(x[i][b], values[i]); } } objective.setMaximization(); final MPSolver.ResultStatus status = solver.solve(); // Check that the problem has an optimal solution. if (status == MPSolver.ResultStatus.OPTIMAL) { System.out.println("Total packed value: " + objective.value()); double totalWeight = 0; for (int b : allBins) { double binWeight = 0; double binValue = 0; System.out.println("Bin " + b); for (int i : allItems) { if (x[i][b].solutionValue() == 1) { System.out.println("Item " + i + " weight: " + weights[i] + " value: " + values[i]); binWeight += weights[i]; binValue += values[i]; } } System.out.println("Packed bin weight: " + binWeight); System.out.println("Packed bin value: " + binValue); totalWeight += binWeight; } System.out.println("Total packed weight: " + totalWeight); } else { System.err.println("The problem does not have an optimal solution."); } } private MultipleKnapsackMip() {} }
C#
// Solve a multiple knapsack problem using a MIP solver. using System; using System.Collections.Generic; using System.Linq; using Google.OrTools.LinearSolver; public class MultipleKnapsackMip { public static void Main() { // Instantiate the data problem. double[] Weights = { 48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36 }; double[] Values = { 10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25 }; int NumItems = Weights.Length; int[] allItems = Enumerable.Range(0, NumItems).ToArray(); double[] BinCapacities = { 100, 100, 100, 100, 100 }; int NumBins = BinCapacities.Length; int[] allBins = Enumerable.Range(0, NumBins).ToArray(); // Create the linear solver with the SCIP backend. Solver solver = Solver.CreateSolver("SCIP"); if (solver is null) { return; } // Variables. Variable[,] x = new Variable[NumItems, NumBins]; foreach (int i in allItems) { foreach (int b in allBins) { x[i, b] = solver.MakeBoolVar($"x_{i}_{b}"); } } // Constraints. // Each item is assigned to at most one bin. foreach (int i in allItems) { Constraint constraint = solver.MakeConstraint(0, 1, ""); foreach (int b in allBins) { constraint.SetCoefficient(x[i, b], 1); } } // The amount packed in each bin cannot exceed its capacity. foreach (int b in allBins) { Constraint constraint = solver.MakeConstraint(0, BinCapacities[b], ""); foreach (int i in allItems) { constraint.SetCoefficient(x[i, b], Weights[i]); } } // Objective. Objective objective = solver.Objective(); foreach (int i in allItems) { foreach (int b in allBins) { objective.SetCoefficient(x[i, b], Values[i]); } } objective.SetMaximization(); Solver.ResultStatus resultStatus = solver.Solve(); // Check that the problem has an optimal solution. if (resultStatus == Solver.ResultStatus.OPTIMAL) { Console.WriteLine($"Total packed value: {solver.Objective().Value()}"); double TotalWeight = 0.0; foreach (int b in allBins) { double BinWeight = 0.0; double BinValue = 0.0; Console.WriteLine("Bin " + b); foreach (int i in allItems) { if (x[i, b].SolutionValue() == 1) { Console.WriteLine($"Item {i} weight: {Weights[i]} values: {Values[i]}"); BinWeight += Weights[i]; BinValue += Values[i]; } } Console.WriteLine("Packed bin weight: " + BinWeight); Console.WriteLine("Packed bin value: " + BinValue); TotalWeight += BinWeight; } Console.WriteLine("Total packed weight: " + TotalWeight); } else { Console.WriteLine("The problem does not have an optimal solution!"); } } }
CP SAT-Lösung
In den folgenden Abschnitten wird beschrieben, wie das Problem mit dem CP-SAT-Löser gelöst wird.
Bibliotheken importieren
Mit dem folgenden Code werden die erforderlichen Bibliotheken importiert.
Python
from ortools.sat.python import cp_model
C++
#include <stdlib.h> #include <map> #include <numeric> #include <tuple> #include <vector> #include "absl/strings/str_format.h" #include "ortools/base/logging.h" #include "ortools/sat/cp_model.h" #include "ortools/sat/cp_model.pb.h" #include "ortools/sat/cp_model_solver.h"
Java
import com.google.ortools.Loader; import com.google.ortools.sat.CpModel; import com.google.ortools.sat.CpSolver; import com.google.ortools.sat.CpSolverStatus; import com.google.ortools.sat.LinearExpr; import com.google.ortools.sat.LinearExprBuilder; import com.google.ortools.sat.Literal; import java.util.ArrayList; import java.util.List; import java.util.stream.IntStream;
C#
using System; using System.Collections.Generic; using System.Linq; using Google.OrTools.Sat; public class MultipleKnapsackSat { public static void Main(String[] args) { // Instantiate the data problem. int[] Weights = { 48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36 }; int[] Values = { 10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25 }; int NumItems = Weights.Length; int[] allItems = Enumerable.Range(0, NumItems).ToArray(); int[] BinCapacities = { 100, 100, 100, 100, 100 }; int NumBins = BinCapacities.Length; int[] allBins = Enumerable.Range(0, NumBins).ToArray(); // Model. CpModel model = new CpModel(); // Variables. ILiteral[,] x = new ILiteral[NumItems, NumBins]; foreach (int i in allItems) { foreach (int b in allBins) { x[i, b] = model.NewBoolVar($"x_{i}_{b}"); } } // Constraints. // Each item is assigned to at most one bin. foreach (int i in allItems) { List<ILiteral> literals = new List<ILiteral>(); foreach (int b in allBins) { literals.Add(x[i, b]); } model.AddAtMostOne(literals); } // The amount packed in each bin cannot exceed its capacity. foreach (int b in allBins) { List<ILiteral> items = new List<ILiteral>(); foreach (int i in allItems) { items.Add(x[i, b]); } model.Add(LinearExpr.WeightedSum(items, Weights) <= BinCapacities[b]); } // Objective. LinearExprBuilder obj = LinearExpr.NewBuilder(); foreach (int i in allItems) { foreach (int b in allBins) { obj.AddTerm(x[i, b], Values[i]); } } model.Maximize(obj); // Solve CpSolver solver = new CpSolver(); CpSolverStatus status = solver.Solve(model); // Print solution. // Check that the problem has a feasible solution. if (status == CpSolverStatus.Optimal || status == CpSolverStatus.Feasible) { Console.WriteLine($"Total packed value: {solver.ObjectiveValue}"); double TotalWeight = 0.0; foreach (int b in allBins) { double BinWeight = 0.0; double BinValue = 0.0; Console.WriteLine($"Bin {b}"); foreach (int i in allItems) { if (solver.BooleanValue(x[i, b])) { Console.WriteLine($"Item {i} weight: {Weights[i]} values: {Values[i]}"); BinWeight += Weights[i]; BinValue += Values[i]; } } Console.WriteLine("Packed bin weight: " + BinWeight); Console.WriteLine("Packed bin value: " + BinValue); TotalWeight += BinWeight; } Console.WriteLine("Total packed weight: " + TotalWeight); } else { Console.WriteLine("No solution found."); } Console.WriteLine("Statistics"); Console.WriteLine($" conflicts: {solver.NumConflicts()}"); Console.WriteLine($" branches : {solver.NumBranches()}"); Console.WriteLine($" wall time: {solver.WallTime()}s"); } }
Modell deklarieren
Mit dem folgenden Code wird das CP-SAT-Modell deklariert.
Python
model = cp_model.CpModel()
C++
CpModelBuilder cp_model;
Java
CpModel model = new CpModel();
C#
CpModel model = new CpModel();
Daten erstellen
Mit dem folgenden Code werden die Daten für das Problem eingerichtet.
Python
data = {} data["weights"] = [48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36] data["values"] = [10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25] assert len(data["weights"]) == len(data["values"]) num_items = len(data["weights"]) all_items = range(num_items) data["bin_capacities"] = [100, 100, 100, 100, 100] num_bins = len(data["bin_capacities"]) all_bins = range(num_bins)
C++
const std::vector<int> weights = { {48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36}}; const std::vector<int> values = { {10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25}}; const int num_items = static_cast<int>(weights.size()); std::vector<int> all_items(num_items); std::iota(all_items.begin(), all_items.end(), 0); const std::vector<int> bin_capacities = {{100, 100, 100, 100, 100}}; const int num_bins = static_cast<int>(bin_capacities.size()); std::vector<int> all_bins(num_bins); std::iota(all_bins.begin(), all_bins.end(), 0);
Java
final int[] weights = {48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36};
final int[] values = {10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25};
final int numItems = weights.length;
final int[] allItems = IntStream.range(0, numItems).toArray();
final int[] binCapacities = {100, 100, 100, 100, 100};
final int numBins = binCapacities.length;
final int[] allBins = IntStream.range(0, numBins).toArray();C#
int[] Weights = { 48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36 };
int[] Values = { 10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25 };
int NumItems = Weights.Length;
int[] allItems = Enumerable.Range(0, NumItems).ToArray();
int[] BinCapacities = { 100, 100, 100, 100, 100 };
int NumBins = BinCapacities.Length;
int[] allBins = Enumerable.Range(0, NumBins).ToArray();Das Array costs entspricht der Tabelle mit den Kosten.
zum Zuweisen von Workern zu Aufgaben (siehe oben).
Variablen erstellen
Mit dem folgenden Code werden binäre Ganzzahlvariablen für das Problem erstellt.
Python
# x[i, b] = 1 if item i is packed in bin b. x = {} for i in all_items: for b in all_bins: x[i, b] = model.new_bool_var(f"x_{i}_{b}")
C++
// x[i, b] = 1 if item i is packed in bin b. std::map<std::tuple<int, int>, BoolVar> x; for (int i : all_items) { for (int b : all_bins) { auto key = std::make_tuple(i, b); x[key] = cp_model.NewBoolVar().WithName(absl::StrFormat("x_%d_%d", i, b)); } }
Java
Literal[][] x = new Literal[numItems][numBins]; for (int i : allItems) { for (int b : allBins) { x[i][b] = model.newBoolVar("x_" + i + "_" + b); } }
C#
ILiteral[,] x = new ILiteral[NumItems, NumBins];
foreach (int i in allItems)
{
foreach (int b in allBins)
{
x[i, b] = model.NewBoolVar($"x_{i}_{b}");
}
}Einschränkungen erstellen
Der folgende Code erstellt die Einschränkungen für das Problem.
Python
# Each item is assigned to at most one bin. for i in all_items: model.add_at_most_one(x[i, b] for b in all_bins) # The amount packed in each bin cannot exceed its capacity. for b in all_bins: model.add( sum(x[i, b] * data["weights"][i] for i in all_items) <= data["bin_capacities"][b] )
C++
// Each item is assigned to at most one bin. for (int i : all_items) { std::vector<BoolVar> copies; for (int b : all_bins) { copies.push_back(x[std::make_tuple(i, b)]); } cp_model.AddAtMostOne(copies); } // The amount packed in each bin cannot exceed its capacity. for (int b : all_bins) { LinearExpr bin_weight; for (int i : all_items) { bin_weight += x[std::make_tuple(i, b)] * weights[i]; } cp_model.AddLessOrEqual(bin_weight, bin_capacities[b]); }
Java
// Each item is assigned to at most one bin. for (int i : allItems) { List<Literal> bins = new ArrayList<>(); for (int b : allBins) { bins.add(x[i][b]); } model.addAtMostOne(bins); } // The amount packed in each bin cannot exceed its capacity. for (int b : allBins) { LinearExprBuilder load = LinearExpr.newBuilder(); for (int i : allItems) { load.addTerm(x[i][b], weights[i]); } model.addLessOrEqual(load, binCapacities[b]); }
C#
// Each item is assigned to at most one bin. foreach (int i in allItems) { List<ILiteral> literals = new List<ILiteral>(); foreach (int b in allBins) { literals.Add(x[i, b]); } model.AddAtMostOne(literals); } // The amount packed in each bin cannot exceed its capacity. foreach (int b in allBins) { List<ILiteral> items = new List<ILiteral>(); foreach (int i in allItems) { items.Add(x[i, b]); } model.Add(LinearExpr.WeightedSum(items, Weights) <= BinCapacities[b]); }
Zielfunktion erstellen
Mit dem folgenden Code wird die Zielfunktion für das Problem erstellt.
Python
# maximize total value of packed items. objective = [] for i in all_items: for b in all_bins: objective.append(cp_model.LinearExpr.term(x[i, b], data["values"][i])) model.maximize(cp_model.LinearExpr.sum(objective))
C++
// Maximize total value of packed items. LinearExpr objective; for (int i : all_items) { for (int b : all_bins) { objective += x[std::make_tuple(i, b)] * values[i]; } } cp_model.Maximize(objective);
Java
// Maximize total value of packed items. LinearExprBuilder obj = LinearExpr.newBuilder(); for (int i : allItems) { for (int b : allBins) { obj.addTerm(x[i][b], values[i]); } } model.maximize(obj);
C#
LinearExprBuilder obj = LinearExpr.NewBuilder(); foreach (int i in allItems) { foreach (int b in allBins) { obj.AddTerm(x[i, b], Values[i]); } } model.Maximize(obj);
Der Wert der Zielfunktion sind die Gesamtkosten für alle Variablen, Löse den Wert 1.
Solver aufrufen
Der folgende Code ruft den Solver auf.
Python
solver = cp_model.CpSolver() status = solver.solve(model)
C++
const CpSolverResponse response = Solve(cp_model.Build());
Java
CpSolver solver = new CpSolver(); final CpSolverStatus status = solver.solve(model);
C#
CpSolver solver = new CpSolver(); CpSolverStatus status = solver.Solve(model);
Lösung drucken
Der folgende Code gibt die Lösung für das Problem aus.
Python
if status == cp_model.OPTIMAL: print(f"Total packed value: {solver.objective_value}") total_weight = 0 for b in all_bins: print(f"Bin {b}") bin_weight = 0 bin_value = 0 for i in all_items: if solver.value(x[i, b]) > 0: print( f'Item:{i} weight:{data["weights"][i]} value:{data["values"][i]}' ) bin_weight += data["weights"][i] bin_value += data["values"][i] print(f"Packed bin weight: {bin_weight}") print(f"Packed bin value: {bin_value}\n") total_weight += bin_weight print(f"Total packed weight: {total_weight}") else: print("The problem does not have an optimal solution.")
C++
if (response.status() == CpSolverStatus::OPTIMAL || response.status() == CpSolverStatus::FEASIBLE) { LOG(INFO) << "Total packed value: " << response.objective_value(); double total_weight = 0.0; for (int b : all_bins) { LOG(INFO) << "Bin " << b; double bin_weight = 0.0; double bin_value = 0.0; for (int i : all_items) { auto key = std::make_tuple(i, b); if (SolutionIntegerValue(response, x[key]) > 0) { LOG(INFO) << "Item " << i << " weight: " << weights[i] << " value: " << values[i]; bin_weight += weights[i]; bin_value += values[i]; } } LOG(INFO) << "Packed bin weight: " << bin_weight; LOG(INFO) << "Packed bin value: " << bin_value; total_weight += bin_weight; } LOG(INFO) << "Total packed weight: " << total_weight; } else { LOG(INFO) << "The problem does not have an optimal solution."; }
Java
// Check that the problem has an optimal solution. if (status == CpSolverStatus.OPTIMAL) { System.out.println("Total packed value: " + solver.objectiveValue()); long totalWeight = 0; for (int b : allBins) { long binWeight = 0; long binValue = 0; System.out.println("Bin " + b); for (int i : allItems) { if (solver.booleanValue(x[i][b])) { System.out.println("Item " + i + " weight: " + weights[i] + " value: " + values[i]); binWeight += weights[i]; binValue += values[i]; } } System.out.println("Packed bin weight: " + binWeight); System.out.println("Packed bin value: " + binValue); totalWeight += binWeight; } System.out.println("Total packed weight: " + totalWeight); } else { System.err.println("The problem does not have an optimal solution."); }
C#
// Check that the problem has a feasible solution. if (status == CpSolverStatus.Optimal || status == CpSolverStatus.Feasible) { Console.WriteLine($"Total packed value: {solver.ObjectiveValue}"); double TotalWeight = 0.0; foreach (int b in allBins) { double BinWeight = 0.0; double BinValue = 0.0; Console.WriteLine($"Bin {b}"); foreach (int i in allItems) { if (solver.BooleanValue(x[i, b])) { Console.WriteLine($"Item {i} weight: {Weights[i]} values: {Values[i]}"); BinWeight += Weights[i]; BinValue += Values[i]; } } Console.WriteLine("Packed bin weight: " + BinWeight); Console.WriteLine("Packed bin value: " + BinValue); TotalWeight += BinWeight; } Console.WriteLine("Total packed weight: " + TotalWeight); } else { Console.WriteLine("No solution found."); }
Hier ist die Ausgabe des Programms.
Total packed value: 395.0 Bin 0 Item 3 - weight: 36 value: 50 Item 13 - weight: 36 value: 30 Packed bin weight: 72 Packed bin value: 80 Bin 1 Item 5 - weight: 48 value: 30 Item 7 - weight: 42 value: 40 Packed bin weight: 90 Packed bin value: 70 Bin 2 Item 1 - weight: 30 value: 30 Item 10 - weight: 30 value: 45 Item 14 - weight: 36 value: 25 Packed bin weight: 96 Packed bin value: 100 Bin 3 Item 2 - weight: 42 value: 25 Item 12 - weight: 42 value: 20 Packed bin weight: 84 Packed bin value: 45 Bin 4 Item 4 - weight: 36 value: 35 Item 8 - weight: 36 value: 30 Item 9 - weight: 24 value: 35 Packed bin weight: 96 Packed bin value: 100 Total packed weight: 438
Programme abschließen
Hier finden Sie die vollständigen Programme für die CP-SAT-Lösung.
Python
"""Solves a multiple knapsack problem using the CP-SAT solver.""" from ortools.sat.python import cp_model def main() -> None: data = {} data["weights"] = [48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36] data["values"] = [10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25] assert len(data["weights"]) == len(data["values"]) num_items = len(data["weights"]) all_items = range(num_items) data["bin_capacities"] = [100, 100, 100, 100, 100] num_bins = len(data["bin_capacities"]) all_bins = range(num_bins) model = cp_model.CpModel() # Variables. # x[i, b] = 1 if item i is packed in bin b. x = {} for i in all_items: for b in all_bins: x[i, b] = model.new_bool_var(f"x_{i}_{b}") # Constraints. # Each item is assigned to at most one bin. for i in all_items: model.add_at_most_one(x[i, b] for b in all_bins) # The amount packed in each bin cannot exceed its capacity. for b in all_bins: model.add( sum(x[i, b] * data["weights"][i] for i in all_items) <= data["bin_capacities"][b] ) # Objective. # maximize total value of packed items. objective = [] for i in all_items: for b in all_bins: objective.append(cp_model.LinearExpr.term(x[i, b], data["values"][i])) model.maximize(cp_model.LinearExpr.sum(objective)) solver = cp_model.CpSolver() status = solver.solve(model) if status == cp_model.OPTIMAL: print(f"Total packed value: {solver.objective_value}") total_weight = 0 for b in all_bins: print(f"Bin {b}") bin_weight = 0 bin_value = 0 for i in all_items: if solver.value(x[i, b]) > 0: print( f'Item:{i} weight:{data["weights"][i]} value:{data["values"][i]}' ) bin_weight += data["weights"][i] bin_value += data["values"][i] print(f"Packed bin weight: {bin_weight}") print(f"Packed bin value: {bin_value}\n") total_weight += bin_weight print(f"Total packed weight: {total_weight}") else: print("The problem does not have an optimal solution.") if __name__ == "__main__": main()
C++
// Solves a multiple knapsack problem using the CP-SAT solver. #include <stdlib.h> #include <map> #include <numeric> #include <tuple> #include <vector> #include "absl/strings/str_format.h" #include "ortools/base/logging.h" #include "ortools/sat/cp_model.h" #include "ortools/sat/cp_model.pb.h" #include "ortools/sat/cp_model_solver.h" namespace operations_research { namespace sat { void MultipleKnapsackSat() { const std::vector<int> weights = { {48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36}}; const std::vector<int> values = { {10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25}}; const int num_items = static_cast<int>(weights.size()); std::vector<int> all_items(num_items); std::iota(all_items.begin(), all_items.end(), 0); const std::vector<int> bin_capacities = {{100, 100, 100, 100, 100}}; const int num_bins = static_cast<int>(bin_capacities.size()); std::vector<int> all_bins(num_bins); std::iota(all_bins.begin(), all_bins.end(), 0); CpModelBuilder cp_model; // Variables. // x[i, b] = 1 if item i is packed in bin b. std::map<std::tuple<int, int>, BoolVar> x; for (int i : all_items) { for (int b : all_bins) { auto key = std::make_tuple(i, b); x[key] = cp_model.NewBoolVar().WithName(absl::StrFormat("x_%d_%d", i, b)); } } // Constraints. // Each item is assigned to at most one bin. for (int i : all_items) { std::vector<BoolVar> copies; for (int b : all_bins) { copies.push_back(x[std::make_tuple(i, b)]); } cp_model.AddAtMostOne(copies); } // The amount packed in each bin cannot exceed its capacity. for (int b : all_bins) { LinearExpr bin_weight; for (int i : all_items) { bin_weight += x[std::make_tuple(i, b)] * weights[i]; } cp_model.AddLessOrEqual(bin_weight, bin_capacities[b]); } // Objective. // Maximize total value of packed items. LinearExpr objective; for (int i : all_items) { for (int b : all_bins) { objective += x[std::make_tuple(i, b)] * values[i]; } } cp_model.Maximize(objective); const CpSolverResponse response = Solve(cp_model.Build()); if (response.status() == CpSolverStatus::OPTIMAL || response.status() == CpSolverStatus::FEASIBLE) { LOG(INFO) << "Total packed value: " << response.objective_value(); double total_weight = 0.0; for (int b : all_bins) { LOG(INFO) << "Bin " << b; double bin_weight = 0.0; double bin_value = 0.0; for (int i : all_items) { auto key = std::make_tuple(i, b); if (SolutionIntegerValue(response, x[key]) > 0) { LOG(INFO) << "Item " << i << " weight: " << weights[i] << " value: " << values[i]; bin_weight += weights[i]; bin_value += values[i]; } } LOG(INFO) << "Packed bin weight: " << bin_weight; LOG(INFO) << "Packed bin value: " << bin_value; total_weight += bin_weight; } LOG(INFO) << "Total packed weight: " << total_weight; } else { LOG(INFO) << "The problem does not have an optimal solution."; } // Statistics. LOG(INFO) << "Statistics"; LOG(INFO) << CpSolverResponseStats(response); } } // namespace sat } // namespace operations_research int main() { operations_research::sat::MultipleKnapsackSat(); return EXIT_SUCCESS; }
Java
// Solves a multiple knapsack problem using the CP-SAT solver. package com.google.ortools.sat.samples; import com.google.ortools.Loader; import com.google.ortools.sat.CpModel; import com.google.ortools.sat.CpSolver; import com.google.ortools.sat.CpSolverStatus; import com.google.ortools.sat.LinearExpr; import com.google.ortools.sat.LinearExprBuilder; import com.google.ortools.sat.Literal; import java.util.ArrayList; import java.util.List; import java.util.stream.IntStream; /** Sample showing how to solve a multiple knapsack problem. */ public class MultipleKnapsackSat { public static void main(String[] args) { Loader.loadNativeLibraries(); // Instantiate the data problem. final int[] weights = {48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36}; final int[] values = {10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25}; final int numItems = weights.length; final int[] allItems = IntStream.range(0, numItems).toArray(); final int[] binCapacities = {100, 100, 100, 100, 100}; final int numBins = binCapacities.length; final int[] allBins = IntStream.range(0, numBins).toArray(); CpModel model = new CpModel(); // Variables. Literal[][] x = new Literal[numItems][numBins]; for (int i : allItems) { for (int b : allBins) { x[i][b] = model.newBoolVar("x_" + i + "_" + b); } } // Constraints. // Each item is assigned to at most one bin. for (int i : allItems) { List<Literal> bins = new ArrayList<>(); for (int b : allBins) { bins.add(x[i][b]); } model.addAtMostOne(bins); } // The amount packed in each bin cannot exceed its capacity. for (int b : allBins) { LinearExprBuilder load = LinearExpr.newBuilder(); for (int i : allItems) { load.addTerm(x[i][b], weights[i]); } model.addLessOrEqual(load, binCapacities[b]); } // Objective. // Maximize total value of packed items. LinearExprBuilder obj = LinearExpr.newBuilder(); for (int i : allItems) { for (int b : allBins) { obj.addTerm(x[i][b], values[i]); } } model.maximize(obj); CpSolver solver = new CpSolver(); final CpSolverStatus status = solver.solve(model); // Check that the problem has an optimal solution. if (status == CpSolverStatus.OPTIMAL) { System.out.println("Total packed value: " + solver.objectiveValue()); long totalWeight = 0; for (int b : allBins) { long binWeight = 0; long binValue = 0; System.out.println("Bin " + b); for (int i : allItems) { if (solver.booleanValue(x[i][b])) { System.out.println("Item " + i + " weight: " + weights[i] + " value: " + values[i]); binWeight += weights[i]; binValue += values[i]; } } System.out.println("Packed bin weight: " + binWeight); System.out.println("Packed bin value: " + binValue); totalWeight += binWeight; } System.out.println("Total packed weight: " + totalWeight); } else { System.err.println("The problem does not have an optimal solution."); } } private MultipleKnapsackSat() {} }
C#
// Solves a multiple knapsack problem using the CP-SAT solver. using System; using System.Collections.Generic; using System.Linq; using Google.OrTools.Sat; public class MultipleKnapsackSat { public static void Main(String[] args) { // Instantiate the data problem. int[] Weights = { 48, 30, 42, 36, 36, 48, 42, 42, 36, 24, 30, 30, 42, 36, 36 }; int[] Values = { 10, 30, 25, 50, 35, 30, 15, 40, 30, 35, 45, 10, 20, 30, 25 }; int NumItems = Weights.Length; int[] allItems = Enumerable.Range(0, NumItems).ToArray(); int[] BinCapacities = { 100, 100, 100, 100, 100 }; int NumBins = BinCapacities.Length; int[] allBins = Enumerable.Range(0, NumBins).ToArray(); // Model. CpModel model = new CpModel(); // Variables. ILiteral[,] x = new ILiteral[NumItems, NumBins]; foreach (int i in allItems) { foreach (int b in allBins) { x[i, b] = model.NewBoolVar($"x_{i}_{b}"); } } // Constraints. // Each item is assigned to at most one bin. foreach (int i in allItems) { List<ILiteral> literals = new List<ILiteral>(); foreach (int b in allBins) { literals.Add(x[i, b]); } model.AddAtMostOne(literals); } // The amount packed in each bin cannot exceed its capacity. foreach (int b in allBins) { List<ILiteral> items = new List<ILiteral>(); foreach (int i in allItems) { items.Add(x[i, b]); } model.Add(LinearExpr.WeightedSum(items, Weights) <= BinCapacities[b]); } // Objective. LinearExprBuilder obj = LinearExpr.NewBuilder(); foreach (int i in allItems) { foreach (int b in allBins) { obj.AddTerm(x[i, b], Values[i]); } } model.Maximize(obj); // Solve CpSolver solver = new CpSolver(); CpSolverStatus status = solver.Solve(model); // Print solution. // Check that the problem has a feasible solution. if (status == CpSolverStatus.Optimal || status == CpSolverStatus.Feasible) { Console.WriteLine($"Total packed value: {solver.ObjectiveValue}"); double TotalWeight = 0.0; foreach (int b in allBins) { double BinWeight = 0.0; double BinValue = 0.0; Console.WriteLine($"Bin {b}"); foreach (int i in allItems) { if (solver.BooleanValue(x[i, b])) { Console.WriteLine($"Item {i} weight: {Weights[i]} values: {Values[i]}"); BinWeight += Weights[i]; BinValue += Values[i]; } } Console.WriteLine("Packed bin weight: " + BinWeight); Console.WriteLine("Packed bin value: " + BinValue); TotalWeight += BinWeight; } Console.WriteLine("Total packed weight: " + TotalWeight); } else { Console.WriteLine("No solution found."); } Console.WriteLine("Statistics"); Console.WriteLine($" conflicts: {solver.NumConflicts()}"); Console.WriteLine($" branches : {solver.NumBranches()}"); Console.WriteLine($" wall time: {solver.WallTime()}s"); } }