이 섹션에서는 Google Cloud의 과제 문제 해결 방법 모두 사용하여 MIP 솔버와 CP-SAT 솔버를 사용합니다.
예
이 예시에서는 작업자 5개 (0~4 번호)와 태스크 4개 (번호: 0~3) 위의 예보다 작업자가 하나 더 있다는 점에 유의해 주세요. 개요.
작업자를 작업에 할당하는 비용은 다음 표를 참조하세요.
| 작업자 | 작업 0 | 작업 1 | 작업 2 | 작업 3 |
|---|---|---|---|---|
| 0 | 90 | 80 | 75 | 70 |
| 1 | 35 | 85 | 55 | 65 |
| 2 | 125 | 95 | 90 | 95 |
| 3 | 45 | 110 | 95 | 115 |
| 4 | 50 | 100 | 90 | 100 |
문제는 각 작업자에게 최대 1개의 태스크, 작업 중인 두 작업자가 없는 상태에서 동일한 태스크에서 총비용을 최소화하는 데 도움이 됩니다 더 많은 작업자가 작업자 한 명에게 작업이 할당되지 않습니다.
MIP 솔루션
다음 섹션에서는 MPSolver 래퍼입니다.
라이브러리 가져오기
다음 코드는 필요한 라이브러리를 가져옵니다.
Python
from ortools.linear_solver import pywraplp
C++
#include <memory> #include <vector> #include "ortools/base/logging.h" #include "ortools/linear_solver/linear_solver.h"
자바
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;
C#
using System; using Google.OrTools.LinearSolver;
데이터 만들기
다음 코드는 문제에 대한 데이터를 생성합니다.
Python
costs = [
[90, 80, 75, 70],
[35, 85, 55, 65],
[125, 95, 90, 95],
[45, 110, 95, 115],
[50, 100, 90, 100],
]
num_workers = len(costs)
num_tasks = len(costs[0])C++
const std::vector<std::vector<double>> costs{ {90, 80, 75, 70}, {35, 85, 55, 65}, {125, 95, 90, 95}, {45, 110, 95, 115}, {50, 100, 90, 100}, }; const int num_workers = costs.size(); const int num_tasks = costs[0].size();
자바
double[][] costs = {
{90, 80, 75, 70},
{35, 85, 55, 65},
{125, 95, 90, 95},
{45, 110, 95, 115},
{50, 100, 90, 100},
};
int numWorkers = costs.length;
int numTasks = costs[0].length;C#
int[,] costs = {
{ 90, 80, 75, 70 }, { 35, 85, 55, 65 }, { 125, 95, 90, 95 }, { 45, 110, 95, 115 }, { 50, 100, 90, 100 },
};
int numWorkers = costs.GetLength(0);
int numTasks = costs.GetLength(1);costs 배열은 비용 표에 해당합니다.
태스크에 작업자 할당(위 참조)
MIP 솔버 선언
다음 코드는 MIP 솔버를 선언합니다.
Python
# Create the mip solver with the SCIP backend. solver = pywraplp.Solver.CreateSolver("SCIP") if not solver: return
C++
// Create the mip solver with the SCIP backend. std::unique_ptr<MPSolver> solver(MPSolver::CreateSolver("SCIP")); if (!solver) { LOG(WARNING) << "SCIP solver unavailable."; return; }
자바
// 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#
Solver solver = Solver.CreateSolver("SCIP"); if (solver is null) { return; }
변수 만들기
다음 코드는 문제에 대한 이진 정수 변수를 생성합니다.
Python
# x[i, j] is an array of 0-1 variables, which will be 1 # if worker i is assigned to task j. x = {} for i in range(num_workers): for j in range(num_tasks): x[i, j] = solver.IntVar(0, 1, "")
C++
// x[i][j] is an array of 0-1 variables, which will be 1 // if worker i is assigned to task j. std::vector<std::vector<const MPVariable*>> x( num_workers, std::vector<const MPVariable*>(num_tasks)); for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { x[i][j] = solver->MakeIntVar(0, 1, ""); } }
자바
// x[i][j] is an array of 0-1 variables, which will be 1 // if worker i is assigned to task j. MPVariable[][] x = new MPVariable[numWorkers][numTasks]; for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { x[i][j] = solver.makeIntVar(0, 1, ""); } }
C#
// x[i, j] is an array of 0-1 variables, which will be 1 // if worker i is assigned to task j. Variable[,] x = new Variable[numWorkers, numTasks]; for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { x[i, j] = solver.MakeIntVar(0, 1, $"worker_{i}_task_{j}"); } }
제약조건 만들기
다음 코드는 문제의 제약 조건을 생성합니다.
Python
# Each worker is assigned to at most 1 task. for i in range(num_workers): solver.Add(solver.Sum([x[i, j] for j in range(num_tasks)]) <= 1) # Each task is assigned to exactly one worker. for j in range(num_tasks): solver.Add(solver.Sum([x[i, j] for i in range(num_workers)]) == 1)
C++
// Each worker is assigned to at most one task. for (int i = 0; i < num_workers; ++i) { LinearExpr worker_sum; for (int j = 0; j < num_tasks; ++j) { worker_sum += x[i][j]; } solver->MakeRowConstraint(worker_sum <= 1.0); } // Each task is assigned to exactly one worker. for (int j = 0; j < num_tasks; ++j) { LinearExpr task_sum; for (int i = 0; i < num_workers; ++i) { task_sum += x[i][j]; } solver->MakeRowConstraint(task_sum == 1.0); }
자바
// Each worker is assigned to at most one task. for (int i = 0; i < numWorkers; ++i) { MPConstraint constraint = solver.makeConstraint(0, 1, ""); for (int j = 0; j < numTasks; ++j) { constraint.setCoefficient(x[i][j], 1); } } // Each task is assigned to exactly one worker. for (int j = 0; j < numTasks; ++j) { MPConstraint constraint = solver.makeConstraint(1, 1, ""); for (int i = 0; i < numWorkers; ++i) { constraint.setCoefficient(x[i][j], 1); } }
C#
// Each worker is assigned to at most one task. for (int i = 0; i < numWorkers; ++i) { Constraint constraint = solver.MakeConstraint(0, 1, ""); for (int j = 0; j < numTasks; ++j) { constraint.SetCoefficient(x[i, j], 1); } } // Each task is assigned to exactly one worker. for (int j = 0; j < numTasks; ++j) { Constraint constraint = solver.MakeConstraint(1, 1, ""); for (int i = 0; i < numWorkers; ++i) { constraint.SetCoefficient(x[i, j], 1); } }
목적 함수 만들기
다음 코드는 문제에 대한 목적 함수를 만듭니다.
Python
objective_terms = [] for i in range(num_workers): for j in range(num_tasks): objective_terms.append(costs[i][j] * x[i, j]) solver.Minimize(solver.Sum(objective_terms))
C++
MPObjective* const objective = solver->MutableObjective(); for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { objective->SetCoefficient(x[i][j], costs[i][j]); } } objective->SetMinimization();
자바
MPObjective objective = solver.objective(); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { objective.setCoefficient(x[i][j], costs[i][j]); } } objective.setMinimization();
C#
Objective objective = solver.Objective(); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { objective.SetCoefficient(x[i, j], costs[i, j]); } } objective.SetMinimization();
목표 함수의 값은 값 1을 반환합니다.
솔버 호출
다음 코드는 솔버를 호출합니다.
Python
print(f"Solving with {solver.SolverVersion()}")
status = solver.Solve()C++
const MPSolver::ResultStatus result_status = solver->Solve();
자바
MPSolver.ResultStatus resultStatus = solver.solve();
C#
Solver.ResultStatus resultStatus = solver.Solve();
솔루션 인쇄
다음 코드는 문제에 대한 솔루션을 출력합니다.
Python
if status == pywraplp.Solver.OPTIMAL or status == pywraplp.Solver.FEASIBLE: print(f"Total cost = {solver.Objective().Value()}\n") for i in range(num_workers): for j in range(num_tasks): # Test if x[i,j] is 1 (with tolerance for floating point arithmetic). if x[i, j].solution_value() > 0.5: print(f"Worker {i} assigned to task {j}." + f" Cost: {costs[i][j]}") else: print("No solution found.")
C++
// Check that the problem has a feasible solution. if (result_status != MPSolver::OPTIMAL && result_status != MPSolver::FEASIBLE) { LOG(FATAL) << "No solution found."; } LOG(INFO) << "Total cost = " << objective->Value() << "\n\n"; for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { // Test if x[i][j] is 0 or 1 (with tolerance for floating point // arithmetic). if (x[i][j]->solution_value() > 0.5) { LOG(INFO) << "Worker " << i << " assigned to task " << j << ". Cost = " << costs[i][j]; } } }
자바
// Check that the problem has a feasible solution. if (resultStatus == MPSolver.ResultStatus.OPTIMAL || resultStatus == MPSolver.ResultStatus.FEASIBLE) { System.out.println("Total cost: " + objective.value() + "\n"); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { // Test if x[i][j] is 0 or 1 (with tolerance for floating point // arithmetic). if (x[i][j].solutionValue() > 0.5) { System.out.println( "Worker " + i + " assigned to task " + j + ". Cost = " + costs[i][j]); } } } } else { System.err.println("No solution found."); }
C#
// Check that the problem has a feasible solution. if (resultStatus == Solver.ResultStatus.OPTIMAL || resultStatus == Solver.ResultStatus.FEASIBLE) { Console.WriteLine($"Total cost: {solver.Objective().Value()}\n"); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { // Test if x[i, j] is 0 or 1 (with tolerance for floating point // arithmetic). if (x[i, j].SolutionValue() > 0.5) { Console.WriteLine($"Worker {i} assigned to task {j}. Cost: {costs[i, j]}"); } } } } else { Console.WriteLine("No solution found."); }
프로그램의 출력은 다음과 같습니다.
Total cost = 265.0 Worker 0 assigned to task 3. Cost = 70 Worker 1 assigned to task 2. Cost = 55 Worker 2 assigned to task 1. Cost = 95 Worker 3 assigned to task 0. Cost = 45
프로그램 이수
다음은 MIP 솔루션을 위한 전체 프로그램입니다.
Python
from ortools.linear_solver import pywraplp def main(): # Data costs = [ [90, 80, 75, 70], [35, 85, 55, 65], [125, 95, 90, 95], [45, 110, 95, 115], [50, 100, 90, 100], ] num_workers = len(costs) num_tasks = len(costs[0]) # Solver # Create the mip solver with the SCIP backend. solver = pywraplp.Solver.CreateSolver("SCIP") if not solver: return # Variables # x[i, j] is an array of 0-1 variables, which will be 1 # if worker i is assigned to task j. x = {} for i in range(num_workers): for j in range(num_tasks): x[i, j] = solver.IntVar(0, 1, "") # Constraints # Each worker is assigned to at most 1 task. for i in range(num_workers): solver.Add(solver.Sum([x[i, j] for j in range(num_tasks)]) <= 1) # Each task is assigned to exactly one worker. for j in range(num_tasks): solver.Add(solver.Sum([x[i, j] for i in range(num_workers)]) == 1) # Objective objective_terms = [] for i in range(num_workers): for j in range(num_tasks): objective_terms.append(costs[i][j] * x[i, j]) solver.Minimize(solver.Sum(objective_terms)) # Solve print(f"Solving with {solver.SolverVersion()}") status = solver.Solve() # Print solution. if status == pywraplp.Solver.OPTIMAL or status == pywraplp.Solver.FEASIBLE: print(f"Total cost = {solver.Objective().Value()}\n") for i in range(num_workers): for j in range(num_tasks): # Test if x[i,j] is 1 (with tolerance for floating point arithmetic). if x[i, j].solution_value() > 0.5: print(f"Worker {i} assigned to task {j}." + f" Cost: {costs[i][j]}") else: print("No solution found.") if __name__ == "__main__": main()
C++
#include <memory> #include <vector> #include "ortools/base/logging.h" #include "ortools/linear_solver/linear_solver.h" namespace operations_research { void AssignmentMip() { // Data const std::vector<std::vector<double>> costs{ {90, 80, 75, 70}, {35, 85, 55, 65}, {125, 95, 90, 95}, {45, 110, 95, 115}, {50, 100, 90, 100}, }; const int num_workers = costs.size(); const int num_tasks = costs[0].size(); // Solver // 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][j] is an array of 0-1 variables, which will be 1 // if worker i is assigned to task j. std::vector<std::vector<const MPVariable*>> x( num_workers, std::vector<const MPVariable*>(num_tasks)); for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { x[i][j] = solver->MakeIntVar(0, 1, ""); } } // Constraints // Each worker is assigned to at most one task. for (int i = 0; i < num_workers; ++i) { LinearExpr worker_sum; for (int j = 0; j < num_tasks; ++j) { worker_sum += x[i][j]; } solver->MakeRowConstraint(worker_sum <= 1.0); } // Each task is assigned to exactly one worker. for (int j = 0; j < num_tasks; ++j) { LinearExpr task_sum; for (int i = 0; i < num_workers; ++i) { task_sum += x[i][j]; } solver->MakeRowConstraint(task_sum == 1.0); } // Objective. MPObjective* const objective = solver->MutableObjective(); for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { objective->SetCoefficient(x[i][j], costs[i][j]); } } objective->SetMinimization(); // Solve const MPSolver::ResultStatus result_status = solver->Solve(); // Print solution. // Check that the problem has a feasible solution. if (result_status != MPSolver::OPTIMAL && result_status != MPSolver::FEASIBLE) { LOG(FATAL) << "No solution found."; } LOG(INFO) << "Total cost = " << objective->Value() << "\n\n"; for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { // Test if x[i][j] is 0 or 1 (with tolerance for floating point // arithmetic). if (x[i][j]->solution_value() > 0.5) { LOG(INFO) << "Worker " << i << " assigned to task " << j << ". Cost = " << costs[i][j]; } } } } } // namespace operations_research int main(int argc, char** argv) { operations_research::AssignmentMip(); return EXIT_SUCCESS; }
자바
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; /** MIP example that solves an assignment problem. */ public class AssignmentMip { public static void main(String[] args) { Loader.loadNativeLibraries(); // Data double[][] costs = { {90, 80, 75, 70}, {35, 85, 55, 65}, {125, 95, 90, 95}, {45, 110, 95, 115}, {50, 100, 90, 100}, }; int numWorkers = costs.length; int numTasks = costs[0].length; // Solver // 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 // x[i][j] is an array of 0-1 variables, which will be 1 // if worker i is assigned to task j. MPVariable[][] x = new MPVariable[numWorkers][numTasks]; for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { x[i][j] = solver.makeIntVar(0, 1, ""); } } // Constraints // Each worker is assigned to at most one task. for (int i = 0; i < numWorkers; ++i) { MPConstraint constraint = solver.makeConstraint(0, 1, ""); for (int j = 0; j < numTasks; ++j) { constraint.setCoefficient(x[i][j], 1); } } // Each task is assigned to exactly one worker. for (int j = 0; j < numTasks; ++j) { MPConstraint constraint = solver.makeConstraint(1, 1, ""); for (int i = 0; i < numWorkers; ++i) { constraint.setCoefficient(x[i][j], 1); } } // Objective MPObjective objective = solver.objective(); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { objective.setCoefficient(x[i][j], costs[i][j]); } } objective.setMinimization(); // Solve MPSolver.ResultStatus resultStatus = solver.solve(); // Print solution. // Check that the problem has a feasible solution. if (resultStatus == MPSolver.ResultStatus.OPTIMAL || resultStatus == MPSolver.ResultStatus.FEASIBLE) { System.out.println("Total cost: " + objective.value() + "\n"); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { // Test if x[i][j] is 0 or 1 (with tolerance for floating point // arithmetic). if (x[i][j].solutionValue() > 0.5) { System.out.println( "Worker " + i + " assigned to task " + j + ". Cost = " + costs[i][j]); } } } } else { System.err.println("No solution found."); } } private AssignmentMip() {} }
C#
using System; using Google.OrTools.LinearSolver; public class AssignmentMip { static void Main() { // Data. int[,] costs = { { 90, 80, 75, 70 }, { 35, 85, 55, 65 }, { 125, 95, 90, 95 }, { 45, 110, 95, 115 }, { 50, 100, 90, 100 }, }; int numWorkers = costs.GetLength(0); int numTasks = costs.GetLength(1); // Solver. Solver solver = Solver.CreateSolver("SCIP"); if (solver is null) { return; } // Variables. // x[i, j] is an array of 0-1 variables, which will be 1 // if worker i is assigned to task j. Variable[,] x = new Variable[numWorkers, numTasks]; for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { x[i, j] = solver.MakeIntVar(0, 1, $"worker_{i}_task_{j}"); } } // Constraints // Each worker is assigned to at most one task. for (int i = 0; i < numWorkers; ++i) { Constraint constraint = solver.MakeConstraint(0, 1, ""); for (int j = 0; j < numTasks; ++j) { constraint.SetCoefficient(x[i, j], 1); } } // Each task is assigned to exactly one worker. for (int j = 0; j < numTasks; ++j) { Constraint constraint = solver.MakeConstraint(1, 1, ""); for (int i = 0; i < numWorkers; ++i) { constraint.SetCoefficient(x[i, j], 1); } } // Objective Objective objective = solver.Objective(); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { objective.SetCoefficient(x[i, j], costs[i, j]); } } objective.SetMinimization(); // Solve Solver.ResultStatus resultStatus = solver.Solve(); // Print solution. // Check that the problem has a feasible solution. if (resultStatus == Solver.ResultStatus.OPTIMAL || resultStatus == Solver.ResultStatus.FEASIBLE) { Console.WriteLine($"Total cost: {solver.Objective().Value()}\n"); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { // Test if x[i, j] is 0 or 1 (with tolerance for floating point // arithmetic). if (x[i, j].SolutionValue() > 0.5) { Console.WriteLine($"Worker {i} assigned to task {j}. Cost: {costs[i, j]}"); } } } } else { Console.WriteLine("No solution found."); } } }
CP SAT 솔루션
다음 섹션에서는 CP-SAT 솔버를 사용하여 문제를 해결하는 방법을 설명합니다.
라이브러리 가져오기
다음 코드는 필요한 라이브러리를 가져옵니다.
Python
import io import pandas as pd from ortools.sat.python import cp_model
C++
#include <stdlib.h> #include <vector> #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"
자바
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 Google.OrTools.Sat;
모델 선언
다음 코드는 CP-SAT 모델을 선언합니다.
Python
model = cp_model.CpModel()
C++
CpModelBuilder cp_model;
자바
CpModel model = new CpModel();
C#
CpModel model = new CpModel();
데이터 만들기
다음 코드는 문제에 대한 데이터를 설정합니다.
Python
data_str = """
worker task cost
w1 t1 90
w1 t2 80
w1 t3 75
w1 t4 70
w2 t1 35
w2 t2 85
w2 t3 55
w2 t4 65
w3 t1 125
w3 t2 95
w3 t3 90
w3 t4 95
w4 t1 45
w4 t2 110
w4 t3 95
w4 t4 115
w5 t1 50
w5 t2 110
w5 t3 90
w5 t4 100
"""
data = pd.read_table(io.StringIO(data_str), sep=r"\s+")C++
const std::vector<std::vector<int>> costs{ {90, 80, 75, 70}, {35, 85, 55, 65}, {125, 95, 90, 95}, {45, 110, 95, 115}, {50, 100, 90, 100}, }; const int num_workers = static_cast<int>(costs.size()); const int num_tasks = static_cast<int>(costs[0].size());
자바
int[][] costs = {
{90, 80, 75, 70},
{35, 85, 55, 65},
{125, 95, 90, 95},
{45, 110, 95, 115},
{50, 100, 90, 100},
};
final int numWorkers = costs.length;
final int numTasks = costs[0].length;
final int[] allWorkers = IntStream.range(0, numWorkers).toArray();
final int[] allTasks = IntStream.range(0, numTasks).toArray();C#
int[,] costs = {
{ 90, 80, 75, 70 }, { 35, 85, 55, 65 }, { 125, 95, 90, 95 }, { 45, 110, 95, 115 }, { 50, 100, 90, 100 },
};
int numWorkers = costs.GetLength(0);
int numTasks = costs.GetLength(1);costs 배열은 비용 표에 해당합니다.
태스크에 작업자 할당(위 참조)
변수 만들기
다음 코드는 문제에 대한 이진 정수 변수를 생성합니다.
Python
x = model.new_bool_var_series(name="x", index=data.index)
C++
// x[i][j] is an array of Boolean variables. x[i][j] is true // if worker i is assigned to task j. std::vector<std::vector<BoolVar>> x(num_workers, std::vector<BoolVar>(num_tasks)); for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { x[i][j] = cp_model.NewBoolVar(); } }
자바
Literal[][] x = new Literal[numWorkers][numTasks]; for (int worker : allWorkers) { for (int task : allTasks) { x[worker][task] = model.newBoolVar("x[" + worker + "," + task + "]"); } }
C#
BoolVar[,] x = new BoolVar[numWorkers, numTasks];
// Variables in a 1-dim array.
for (int worker = 0; worker < numWorkers; ++worker)
{
for (int task = 0; task < numTasks; ++task)
{
x[worker, task] = model.NewBoolVar($"worker_{worker}_task_{task}");
}
}제약조건 만들기
다음 코드는 문제의 제약 조건을 생성합니다.
Python
# Each worker is assigned to at most one task. for unused_name, tasks in data.groupby("worker"): model.add_at_most_one(x[tasks.index]) # Each task is assigned to exactly one worker. for unused_name, workers in data.groupby("task"): model.add_exactly_one(x[workers.index])
C++
// Each worker is assigned to at most one task. for (int i = 0; i < num_workers; ++i) { cp_model.AddAtMostOne(x[i]); } // Each task is assigned to exactly one worker. for (int j = 0; j < num_tasks; ++j) { std::vector<BoolVar> tasks; for (int i = 0; i < num_workers; ++i) { tasks.push_back(x[i][j]); } cp_model.AddExactlyOne(tasks); }
자바
// Each worker is assigned to at most one task. for (int worker : allWorkers) { List<Literal> tasks = new ArrayList<>(); for (int task : allTasks) { tasks.add(x[worker][task]); } model.addAtMostOne(tasks); } // Each task is assigned to exactly one worker. for (int task : allTasks) { List<Literal> workers = new ArrayList<>(); for (int worker : allWorkers) { workers.add(x[worker][task]); } model.addExactlyOne(workers); }
C#
// Each worker is assigned to at most one task. for (int worker = 0; worker < numWorkers; ++worker) { List<ILiteral> tasks = new List<ILiteral>(); for (int task = 0; task < numTasks; ++task) { tasks.Add(x[worker, task]); } model.AddAtMostOne(tasks); } // Each task is assigned to exactly one worker. for (int task = 0; task < numTasks; ++task) { List<ILiteral> workers = new List<ILiteral>(); for (int worker = 0; worker < numWorkers; ++worker) { workers.Add(x[worker, task]); } model.AddExactlyOne(workers); }
목적 함수 만들기
다음 코드는 문제에 대한 목적 함수를 만듭니다.
Python
model.minimize(data.cost.dot(x))
C++
LinearExpr total_cost; for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { total_cost += x[i][j] * costs[i][j]; } } cp_model.Minimize(total_cost);
자바
LinearExprBuilder obj = LinearExpr.newBuilder(); for (int worker : allWorkers) { for (int task : allTasks) { obj.addTerm(x[worker][task], costs[worker][task]); } } model.minimize(obj);
C#
LinearExprBuilder obj = LinearExpr.NewBuilder(); for (int worker = 0; worker < numWorkers; ++worker) { for (int task = 0; task < numTasks; ++task) { obj.AddTerm((IntVar)x[worker, task], costs[worker, task]); } } model.Minimize(obj);
목표 함수의 값은 값 1을 반환합니다.
솔버 호출
다음 코드는 솔버를 호출합니다.
Python
solver = cp_model.CpSolver() status = solver.solve(model)
C++
const CpSolverResponse response = Solve(cp_model.Build());
자바
CpSolver solver = new CpSolver(); CpSolverStatus status = solver.solve(model);
C#
CpSolver solver = new CpSolver(); CpSolverStatus status = solver.Solve(model); Console.WriteLine($"Solve status: {status}");
솔루션 인쇄
다음 코드는 문제에 대한 솔루션을 출력합니다.
Python
if status == cp_model.OPTIMAL or status == cp_model.FEASIBLE: print(f"Total cost = {solver.objective_value}\n") selected = data.loc[solver.boolean_values(x).loc[lambda x: x].index] for unused_index, row in selected.iterrows(): print(f"{row.task} assigned to {row.worker} with a cost of {row.cost}") elif status == cp_model.INFEASIBLE: print("No solution found") else: print("Something is wrong, check the status and the log of the solve")
C++
if (response.status() == CpSolverStatus::INFEASIBLE) { LOG(FATAL) << "No solution found."; } LOG(INFO) << "Total cost: " << response.objective_value(); LOG(INFO); for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { if (SolutionBooleanValue(response, x[i][j])) { LOG(INFO) << "Task " << i << " assigned to worker " << j << ". Cost: " << costs[i][j]; } } }
자바
// Check that the problem has a feasible solution. if (status == CpSolverStatus.OPTIMAL || status == CpSolverStatus.FEASIBLE) { System.out.println("Total cost: " + solver.objectiveValue() + "\n"); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { if (solver.booleanValue(x[i][j])) { System.out.println( "Worker " + i + " assigned to task " + j + ". Cost: " + costs[i][j]); } } } } else { System.err.println("No solution found."); }
C#
// Check that the problem has a feasible solution. if (status == CpSolverStatus.Optimal || status == CpSolverStatus.Feasible) { Console.WriteLine($"Total cost: {solver.ObjectiveValue}\n"); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { if (solver.Value(x[i, j]) > 0.5) { Console.WriteLine($"Worker {i} assigned to task {j}. Cost: {costs[i, j]}"); } } } } else { Console.WriteLine("No solution found."); }
프로그램의 출력은 다음과 같습니다.
Total cost = 265 Worker 0 assigned to task 3 Cost = 70 Worker 1 assigned to task 2 Cost = 55 Worker 2 assigned to task 1 Cost = 95 Worker 3 assigned to task 0 Cost = 45
프로그램 이수
다음은 CP-SAT 솔루션을 위한 전체 프로그램입니다.
Python
import io import pandas as pd from ortools.sat.python import cp_model def main() -> None: # Data data_str = """ worker task cost w1 t1 90 w1 t2 80 w1 t3 75 w1 t4 70 w2 t1 35 w2 t2 85 w2 t3 55 w2 t4 65 w3 t1 125 w3 t2 95 w3 t3 90 w3 t4 95 w4 t1 45 w4 t2 110 w4 t3 95 w4 t4 115 w5 t1 50 w5 t2 110 w5 t3 90 w5 t4 100 """ data = pd.read_table(io.StringIO(data_str), sep=r"\s+") # Model model = cp_model.CpModel() # Variables x = model.new_bool_var_series(name="x", index=data.index) # Constraints # Each worker is assigned to at most one task. for unused_name, tasks in data.groupby("worker"): model.add_at_most_one(x[tasks.index]) # Each task is assigned to exactly one worker. for unused_name, workers in data.groupby("task"): model.add_exactly_one(x[workers.index]) # Objective model.minimize(data.cost.dot(x)) # Solve solver = cp_model.CpSolver() status = solver.solve(model) # Print solution. if status == cp_model.OPTIMAL or status == cp_model.FEASIBLE: print(f"Total cost = {solver.objective_value}\n") selected = data.loc[solver.boolean_values(x).loc[lambda x: x].index] for unused_index, row in selected.iterrows(): print(f"{row.task} assigned to {row.worker} with a cost of {row.cost}") elif status == cp_model.INFEASIBLE: print("No solution found") else: print("Something is wrong, check the status and the log of the solve") if __name__ == "__main__": main()
C++
#include <stdlib.h> #include <vector> #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 IntegerProgrammingExample() { // Data const std::vector<std::vector<int>> costs{ {90, 80, 75, 70}, {35, 85, 55, 65}, {125, 95, 90, 95}, {45, 110, 95, 115}, {50, 100, 90, 100}, }; const int num_workers = static_cast<int>(costs.size()); const int num_tasks = static_cast<int>(costs[0].size()); // Model CpModelBuilder cp_model; // Variables // x[i][j] is an array of Boolean variables. x[i][j] is true // if worker i is assigned to task j. std::vector<std::vector<BoolVar>> x(num_workers, std::vector<BoolVar>(num_tasks)); for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { x[i][j] = cp_model.NewBoolVar(); } } // Constraints // Each worker is assigned to at most one task. for (int i = 0; i < num_workers; ++i) { cp_model.AddAtMostOne(x[i]); } // Each task is assigned to exactly one worker. for (int j = 0; j < num_tasks; ++j) { std::vector<BoolVar> tasks; for (int i = 0; i < num_workers; ++i) { tasks.push_back(x[i][j]); } cp_model.AddExactlyOne(tasks); } // Objective LinearExpr total_cost; for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { total_cost += x[i][j] * costs[i][j]; } } cp_model.Minimize(total_cost); // Solve const CpSolverResponse response = Solve(cp_model.Build()); // Print solution. if (response.status() == CpSolverStatus::INFEASIBLE) { LOG(FATAL) << "No solution found."; } LOG(INFO) << "Total cost: " << response.objective_value(); LOG(INFO); for (int i = 0; i < num_workers; ++i) { for (int j = 0; j < num_tasks; ++j) { if (SolutionBooleanValue(response, x[i][j])) { LOG(INFO) << "Task " << i << " assigned to worker " << j << ". Cost: " << costs[i][j]; } } } } } // namespace sat } // namespace operations_research int main(int argc, char** argv) { operations_research::sat::IntegerProgrammingExample(); return EXIT_SUCCESS; }
자바
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; /** Assignment problem. */ public class AssignmentSat { public static void main(String[] args) { Loader.loadNativeLibraries(); // Data int[][] costs = { {90, 80, 75, 70}, {35, 85, 55, 65}, {125, 95, 90, 95}, {45, 110, 95, 115}, {50, 100, 90, 100}, }; final int numWorkers = costs.length; final int numTasks = costs[0].length; final int[] allWorkers = IntStream.range(0, numWorkers).toArray(); final int[] allTasks = IntStream.range(0, numTasks).toArray(); // Model CpModel model = new CpModel(); // Variables Literal[][] x = new Literal[numWorkers][numTasks]; for (int worker : allWorkers) { for (int task : allTasks) { x[worker][task] = model.newBoolVar("x[" + worker + "," + task + "]"); } } // Constraints // Each worker is assigned to at most one task. for (int worker : allWorkers) { List<Literal> tasks = new ArrayList<>(); for (int task : allTasks) { tasks.add(x[worker][task]); } model.addAtMostOne(tasks); } // Each task is assigned to exactly one worker. for (int task : allTasks) { List<Literal> workers = new ArrayList<>(); for (int worker : allWorkers) { workers.add(x[worker][task]); } model.addExactlyOne(workers); } // Objective LinearExprBuilder obj = LinearExpr.newBuilder(); for (int worker : allWorkers) { for (int task : allTasks) { obj.addTerm(x[worker][task], costs[worker][task]); } } model.minimize(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) { System.out.println("Total cost: " + solver.objectiveValue() + "\n"); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { if (solver.booleanValue(x[i][j])) { System.out.println( "Worker " + i + " assigned to task " + j + ". Cost: " + costs[i][j]); } } } } else { System.err.println("No solution found."); } } private AssignmentSat() {} }
C#
using System; using System.Collections.Generic; using Google.OrTools.Sat; public class AssignmentSat { public static void Main(String[] args) { // Data. int[,] costs = { { 90, 80, 75, 70 }, { 35, 85, 55, 65 }, { 125, 95, 90, 95 }, { 45, 110, 95, 115 }, { 50, 100, 90, 100 }, }; int numWorkers = costs.GetLength(0); int numTasks = costs.GetLength(1); // Model. CpModel model = new CpModel(); // Variables. BoolVar[,] x = new BoolVar[numWorkers, numTasks]; // Variables in a 1-dim array. for (int worker = 0; worker < numWorkers; ++worker) { for (int task = 0; task < numTasks; ++task) { x[worker, task] = model.NewBoolVar($"worker_{worker}_task_{task}"); } } // Constraints // Each worker is assigned to at most one task. for (int worker = 0; worker < numWorkers; ++worker) { List<ILiteral> tasks = new List<ILiteral>(); for (int task = 0; task < numTasks; ++task) { tasks.Add(x[worker, task]); } model.AddAtMostOne(tasks); } // Each task is assigned to exactly one worker. for (int task = 0; task < numTasks; ++task) { List<ILiteral> workers = new List<ILiteral>(); for (int worker = 0; worker < numWorkers; ++worker) { workers.Add(x[worker, task]); } model.AddExactlyOne(workers); } // Objective LinearExprBuilder obj = LinearExpr.NewBuilder(); for (int worker = 0; worker < numWorkers; ++worker) { for (int task = 0; task < numTasks; ++task) { obj.AddTerm((IntVar)x[worker, task], costs[worker, task]); } } model.Minimize(obj); // Solve CpSolver solver = new CpSolver(); CpSolverStatus status = solver.Solve(model); Console.WriteLine($"Solve status: {status}"); // Print solution. // Check that the problem has a feasible solution. if (status == CpSolverStatus.Optimal || status == CpSolverStatus.Feasible) { Console.WriteLine($"Total cost: {solver.ObjectiveValue}\n"); for (int i = 0; i < numWorkers; ++i) { for (int j = 0; j < numTasks; ++j) { if (solver.Value(x[i, j]) > 0.5) { Console.WriteLine($"Worker {i} assigned to task {j}. Cost: {costs[i, j]}"); } } } } else { Console.WriteLine("No solution found."); } Console.WriteLine("Statistics"); Console.WriteLine($" - conflicts : {solver.NumConflicts()}"); Console.WriteLine($" - branches : {solver.NumBranches()}"); Console.WriteLine($" - wall time : {solver.WallTime()}s"); } }