יש גרסאות רבות של בעיית ההקצאה, עם מגבלות נוספות על העובדים או המשימות. בדוגמה הבאה, שישה עובדים מחולקים לשני צוותים, וכל צוות יכול לבצע שתי משימות לכל היותר.
בקטעים הבאים מוצגת תוכנית ב-Python שפותרת את הבעיה הזו באמצעות ה-CP-SAT או הפותר MIP. בקטע הקצאה עם צוותים תוכלו למצוא פתרון שיכול לעזור בפתרון הבעיה של הכלי לפתרון בעיות בעלות מינימליות.
פתרון CP-SAT
קודם כל, נבחן את הפתרון של CP-SAT לבעיה.
ייבוא הספריות
הקוד הבא מייבא את הספרייה הנדרשת.
Python
from ortools.sat.python import cp_model
C++
#include <stdlib.h> #include <numeric> #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;
הגדרת הנתונים
הקוד הבא יוצר את הנתונים עבור התוכנה.
Python
costs = [
[90, 76, 75, 70],
[35, 85, 55, 65],
[125, 95, 90, 105],
[45, 110, 95, 115],
[60, 105, 80, 75],
[45, 65, 110, 95],
]
num_workers = len(costs)
num_tasks = len(costs[0])
team1 = [0, 2, 4]
team2 = [1, 3, 5]
# Maximum total of tasks for any team
team_max = 2
C++
const std::vector<std::vector<int>> costs = {{
{{90, 76, 75, 70}},
{{35, 85, 55, 65}},
{{125, 95, 90, 105}},
{{45, 110, 95, 115}},
{{60, 105, 80, 75}},
{{45, 65, 110, 95}},
}};
const int num_workers = static_cast<int>(costs.size());
std::vector<int> all_workers(num_workers);
std::iota(all_workers.begin(), all_workers.end(), 0);
const int num_tasks = static_cast<int>(costs[0].size());
std::vector<int> all_tasks(num_tasks);
std::iota(all_tasks.begin(), all_tasks.end(), 0);
const std::vector<int> team1 = {{0, 2, 4}};
const std::vector<int> team2 = {{1, 3, 5}};
// Maximum total of tasks for any team
const int team_max = 2;
Java
int[][] costs = {
{90, 76, 75, 70},
{35, 85, 55, 65},
{125, 95, 90, 105},
{45, 110, 95, 115},
{60, 105, 80, 75},
{45, 65, 110, 95},
};
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();
final int[] team1 = {0, 2, 4};
final int[] team2 = {1, 3, 5};
// Maximum total of tasks for any team
final int teamMax = 2;
C#
int[,] costs = {
{ 90, 76, 75, 70 }, { 35, 85, 55, 65 }, { 125, 95, 90, 105 },
{ 45, 110, 95, 115 }, { 60, 105, 80, 75 }, { 45, 65, 110, 95 },
};
int numWorkers = costs.GetLength(0);
int numTasks = costs.GetLength(1);
int[] allWorkers = Enumerable.Range(0, numWorkers).ToArray();
int[] allTasks = Enumerable.Range(0, numTasks).ToArray();
int[] team1 = { 0, 2, 4 };
int[] team2 = { 1, 3, 5 };
// Maximum total of tasks for any team
int teamMax = 2;
יוצרים את המודל
הקוד הבא יוצר את המודל.
Python
model = cp_model.CpModel()
C++
CpModelBuilder cp_model;
Java
CpModel model = new CpModel();
C#
CpModel model = new CpModel();
יצירת המשתנים
הקוד הבא יוצר מערך של משתנים בשביל הבעיה.
Python
x = {}
for worker in range(num_workers):
for task in range(num_tasks):
x[worker, task] = model.new_bool_var(f"x[{worker},{task}]")
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 worker : all_workers) {
for (int task : all_tasks) {
x[worker][task] = cp_model.NewBoolVar().WithName(
absl::StrFormat("x[%d,%d]", worker, task));
}
}
Java
Literal[][] x = new Literal[numWorkers][numTasks];
// Variables in a 1-dim array.
for (int worker : allWorkers) {
for (int task : allTasks) {
x[worker][task] = model.newBoolVar("x[" + worker + "," + task + "]");
}
}
C#
BoolVar[,] x = new BoolVar[numWorkers, numTasks];
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
x[worker, task] = model.NewBoolVar($"x[{worker},{task}]");
}
}
לכל צמד של עובד ומשימה יש משתנה אחד. שימו לב שהעובדים ממוספרים כ-0 - 5, בעוד שהמשימות ממוספרות ב-0 - 3, בניגוד לדוגמה המקורית, שבה צריך למספר את כל הצמתים באופן שונה, בהתאם לפתרון של זרימת העלויות המינימלית.
הוספת האילוצים
הקוד הבא יוצר את המגבלות עבור התוכנה.
Python
# Each worker is assigned to at most one task.
for worker in range(num_workers):
model.add_at_most_one(x[worker, task] for task in range(num_tasks))
# Each task is assigned to exactly one worker.
for task in range(num_tasks):
model.add_exactly_one(x[worker, task] for worker in range(num_workers))
# Each team takes at most two tasks.
team1_tasks = []
for worker in team1:
for task in range(num_tasks):
team1_tasks.append(x[worker, task])
model.add(sum(team1_tasks) <= team_max)
team2_tasks = []
for worker in team2:
for task in range(num_tasks):
team2_tasks.append(x[worker, task])
model.add(sum(team2_tasks) <= team_max)
C++
// Each worker is assigned to at most one task.
for (int worker : all_workers) {
cp_model.AddAtMostOne(x[worker]);
}
// Each task is assigned to exactly one worker.
for (int task : all_tasks) {
std::vector<BoolVar> tasks;
for (int worker : all_workers) {
tasks.push_back(x[worker][task]);
}
cp_model.AddExactlyOne(tasks);
}
// Each team takes at most two tasks.
LinearExpr team1_tasks;
for (int worker : team1) {
for (int task : all_tasks) {
team1_tasks += x[worker][task];
}
}
cp_model.AddLessOrEqual(team1_tasks, team_max);
LinearExpr team2_tasks;
for (int worker : team2) {
for (int task : all_tasks) {
team2_tasks += x[worker][task];
}
}
cp_model.AddLessOrEqual(team2_tasks, team_max);
Java
// 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);
}
// Each team takes at most two tasks.
LinearExprBuilder team1Tasks = LinearExpr.newBuilder();
for (int worker : team1) {
for (int task : allTasks) {
team1Tasks.add(x[worker][task]);
}
}
model.addLessOrEqual(team1Tasks, teamMax);
LinearExprBuilder team2Tasks = LinearExpr.newBuilder();
for (int worker : team2) {
for (int task : allTasks) {
team2Tasks.add(x[worker][task]);
}
}
model.addLessOrEqual(team2Tasks, teamMax);
C#
// Each worker is assigned to at most one task.
foreach (int worker in allWorkers)
{
List<ILiteral> tasks = new List<ILiteral>();
foreach (int task in allTasks)
{
tasks.Add(x[worker, task]);
}
model.AddAtMostOne(tasks);
}
// Each task is assigned to exactly one worker.
foreach (int task in allTasks)
{
List<ILiteral> workers = new List<ILiteral>();
foreach (int worker in allWorkers)
{
workers.Add(x[worker, task]);
}
model.AddExactlyOne(workers);
}
// Each team takes at most two tasks.
List<IntVar> team1Tasks = new List<IntVar>();
foreach (int worker in team1)
{
foreach (int task in allTasks)
{
team1Tasks.Add(x[worker, task]);
}
}
model.Add(LinearExpr.Sum(team1Tasks.ToArray()) <= teamMax);
List<IntVar> team2Tasks = new List<IntVar>();
foreach (int worker in team2)
{
foreach (int task in allTasks)
{
team2Tasks.Add(x[worker, task]);
}
}
model.Add(LinearExpr.Sum(team2Tasks.ToArray()) <= teamMax);
יצירת היעד
הקוד הבא יוצר את פונקציית היעד.
Python
objective_terms = []
for worker in range(num_workers):
for task in range(num_tasks):
objective_terms.append(costs[worker][task] * x[worker, task])
model.minimize(sum(objective_terms))
C++
LinearExpr total_cost;
for (int worker : all_workers) {
for (int task : all_tasks) {
total_cost += x[worker][task] * costs[worker][task];
}
}
cp_model.Minimize(total_cost);
Java
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();
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
obj.AddTerm(x[worker, task], costs[worker, task]);
}
}
model.Minimize(obj);
הערך של פונקציית היעד הוא העלות הכוללת של כל המשתנים שהפותר מקצה להם את הערך 1.
מזמינים את הפותר
הקוד הבא מפעיל את הפותר ומציג את התוצאות.
Python
solver = cp_model.CpSolver() status = solver.solve(model)
C++
const CpSolverResponse response = Solve(cp_model.Build());
Java
CpSolver solver = new CpSolver(); CpSolverStatus status = solver.solve(model);
C#
CpSolver solver = new CpSolver();
CpSolverStatus status = solver.Solve(model);
Console.WriteLine($"Solve status: {status}");
הצגת התוצאות
עכשיו אפשר להדפיס את הפתרון.
Python
if status == cp_model.OPTIMAL or status == cp_model.FEASIBLE:
print(f"Total cost = {solver.objective_value}\n")
for worker in range(num_workers):
for task in range(num_tasks):
if solver.boolean_value(x[worker, task]):
print(
f"Worker {worker} assigned to task {task}."
+ f" Cost = {costs[worker][task]}"
)
else:
print("No solution found.")
C++
if (response.status() == CpSolverStatus::INFEASIBLE) {
LOG(FATAL) << "No solution found.";
}
LOG(INFO) << "Total cost: " << response.objective_value();
LOG(INFO);
for (int worker : all_workers) {
for (int task : all_tasks) {
if (SolutionBooleanValue(response, x[worker][task])) {
LOG(INFO) << "Worker " << worker << " assigned to task " << task
<< ". Cost: " << costs[worker][task];
}
}
}
Java
// 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 worker : allWorkers) {
for (int task : allTasks) {
if (solver.booleanValue(x[worker][task])) {
System.out.println("Worker " + worker + " assigned to task " + task
+ ". Cost: " + costs[worker][task]);
}
}
}
} 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($"Total cost: {solver.ObjectiveValue}\n");
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
if (solver.Value(x[worker, task]) > 0.5)
{
Console.WriteLine($"Worker {worker} assigned to task {task}. " +
$"Cost: {costs[worker, task]}");
}
}
}
}
else
{
Console.WriteLine("No solution found.");
}
הנה הפלט של התוכנה.
Total cost: 250 Worker 0 assigned to task 2. Cost = 75 Worker 1 assigned to task 0. Cost = 35 Worker 4 assigned to task 3. Cost = 75 Worker 5 assigned to task 1. Cost = 65 Time = 6 milliseconds
התוכנית כולה
הנה התוכנית כולה.
Python
"""Solves a simple assignment problem."""
from ortools.sat.python import cp_model
def main() -> None:
# Data
costs = [
[90, 76, 75, 70],
[35, 85, 55, 65],
[125, 95, 90, 105],
[45, 110, 95, 115],
[60, 105, 80, 75],
[45, 65, 110, 95],
]
num_workers = len(costs)
num_tasks = len(costs[0])
team1 = [0, 2, 4]
team2 = [1, 3, 5]
# Maximum total of tasks for any team
team_max = 2
# Model
model = cp_model.CpModel()
# Variables
x = {}
for worker in range(num_workers):
for task in range(num_tasks):
x[worker, task] = model.new_bool_var(f"x[{worker},{task}]")
# Constraints
# Each worker is assigned to at most one task.
for worker in range(num_workers):
model.add_at_most_one(x[worker, task] for task in range(num_tasks))
# Each task is assigned to exactly one worker.
for task in range(num_tasks):
model.add_exactly_one(x[worker, task] for worker in range(num_workers))
# Each team takes at most two tasks.
team1_tasks = []
for worker in team1:
for task in range(num_tasks):
team1_tasks.append(x[worker, task])
model.add(sum(team1_tasks) <= team_max)
team2_tasks = []
for worker in team2:
for task in range(num_tasks):
team2_tasks.append(x[worker, task])
model.add(sum(team2_tasks) <= team_max)
# Objective
objective_terms = []
for worker in range(num_workers):
for task in range(num_tasks):
objective_terms.append(costs[worker][task] * x[worker, task])
model.minimize(sum(objective_terms))
# 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")
for worker in range(num_workers):
for task in range(num_tasks):
if solver.boolean_value(x[worker, task]):
print(
f"Worker {worker} assigned to task {task}."
+ f" Cost = {costs[worker][task]}"
)
else:
print("No solution found.")
if __name__ == "__main__":
main()
C++
// Solve a simple assignment problem.
#include <stdlib.h>
#include <numeric>
#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 AssignmentTeamsSat() {
// Data
const std::vector<std::vector<int>> costs = {{
{{90, 76, 75, 70}},
{{35, 85, 55, 65}},
{{125, 95, 90, 105}},
{{45, 110, 95, 115}},
{{60, 105, 80, 75}},
{{45, 65, 110, 95}},
}};
const int num_workers = static_cast<int>(costs.size());
std::vector<int> all_workers(num_workers);
std::iota(all_workers.begin(), all_workers.end(), 0);
const int num_tasks = static_cast<int>(costs[0].size());
std::vector<int> all_tasks(num_tasks);
std::iota(all_tasks.begin(), all_tasks.end(), 0);
const std::vector<int> team1 = {{0, 2, 4}};
const std::vector<int> team2 = {{1, 3, 5}};
// Maximum total of tasks for any team
const int team_max = 2;
// 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 worker : all_workers) {
for (int task : all_tasks) {
x[worker][task] = cp_model.NewBoolVar().WithName(
absl::StrFormat("x[%d,%d]", worker, task));
}
}
// Constraints
// Each worker is assigned to at most one task.
for (int worker : all_workers) {
cp_model.AddAtMostOne(x[worker]);
}
// Each task is assigned to exactly one worker.
for (int task : all_tasks) {
std::vector<BoolVar> tasks;
for (int worker : all_workers) {
tasks.push_back(x[worker][task]);
}
cp_model.AddExactlyOne(tasks);
}
// Each team takes at most two tasks.
LinearExpr team1_tasks;
for (int worker : team1) {
for (int task : all_tasks) {
team1_tasks += x[worker][task];
}
}
cp_model.AddLessOrEqual(team1_tasks, team_max);
LinearExpr team2_tasks;
for (int worker : team2) {
for (int task : all_tasks) {
team2_tasks += x[worker][task];
}
}
cp_model.AddLessOrEqual(team2_tasks, team_max);
// Objective
LinearExpr total_cost;
for (int worker : all_workers) {
for (int task : all_tasks) {
total_cost += x[worker][task] * costs[worker][task];
}
}
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 worker : all_workers) {
for (int task : all_tasks) {
if (SolutionBooleanValue(response, x[worker][task])) {
LOG(INFO) << "Worker " << worker << " assigned to task " << task
<< ". Cost: " << costs[worker][task];
}
}
}
}
} // namespace sat
} // namespace operations_research
int main(int argc, char** argv) {
operations_research::sat::AssignmentTeamsSat();
return EXIT_SUCCESS;
}
Java
// CP-SAT example that solves an assignment problem.
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 AssignmentTeamsSat {
public static void main(String[] args) {
Loader.loadNativeLibraries();
// Data
int[][] costs = {
{90, 76, 75, 70},
{35, 85, 55, 65},
{125, 95, 90, 105},
{45, 110, 95, 115},
{60, 105, 80, 75},
{45, 65, 110, 95},
};
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();
final int[] team1 = {0, 2, 4};
final int[] team2 = {1, 3, 5};
// Maximum total of tasks for any team
final int teamMax = 2;
// Model
CpModel model = new CpModel();
// Variables
Literal[][] x = new Literal[numWorkers][numTasks];
// Variables in a 1-dim array.
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);
}
// Each team takes at most two tasks.
LinearExprBuilder team1Tasks = LinearExpr.newBuilder();
for (int worker : team1) {
for (int task : allTasks) {
team1Tasks.add(x[worker][task]);
}
}
model.addLessOrEqual(team1Tasks, teamMax);
LinearExprBuilder team2Tasks = LinearExpr.newBuilder();
for (int worker : team2) {
for (int task : allTasks) {
team2Tasks.add(x[worker][task]);
}
}
model.addLessOrEqual(team2Tasks, teamMax);
// 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 worker : allWorkers) {
for (int task : allTasks) {
if (solver.booleanValue(x[worker][task])) {
System.out.println("Worker " + worker + " assigned to task " + task
+ ". Cost: " + costs[worker][task]);
}
}
}
} else {
System.err.println("No solution found.");
}
}
private AssignmentTeamsSat() {}
}
C#
using System;
using System.Collections.Generic;
using System.Linq;
using Google.OrTools.Sat;
public class AssignmentTeamsSat
{
public static void Main(String[] args)
{
// Data.
int[,] costs = {
{ 90, 76, 75, 70 }, { 35, 85, 55, 65 }, { 125, 95, 90, 105 },
{ 45, 110, 95, 115 }, { 60, 105, 80, 75 }, { 45, 65, 110, 95 },
};
int numWorkers = costs.GetLength(0);
int numTasks = costs.GetLength(1);
int[] allWorkers = Enumerable.Range(0, numWorkers).ToArray();
int[] allTasks = Enumerable.Range(0, numTasks).ToArray();
int[] team1 = { 0, 2, 4 };
int[] team2 = { 1, 3, 5 };
// Maximum total of tasks for any team
int teamMax = 2;
// Model.
CpModel model = new CpModel();
// Variables.
BoolVar[,] x = new BoolVar[numWorkers, numTasks];
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
x[worker, task] = model.NewBoolVar($"x[{worker},{task}]");
}
}
// Constraints
// Each worker is assigned to at most one task.
foreach (int worker in allWorkers)
{
List<ILiteral> tasks = new List<ILiteral>();
foreach (int task in allTasks)
{
tasks.Add(x[worker, task]);
}
model.AddAtMostOne(tasks);
}
// Each task is assigned to exactly one worker.
foreach (int task in allTasks)
{
List<ILiteral> workers = new List<ILiteral>();
foreach (int worker in allWorkers)
{
workers.Add(x[worker, task]);
}
model.AddExactlyOne(workers);
}
// Each team takes at most two tasks.
List<IntVar> team1Tasks = new List<IntVar>();
foreach (int worker in team1)
{
foreach (int task in allTasks)
{
team1Tasks.Add(x[worker, task]);
}
}
model.Add(LinearExpr.Sum(team1Tasks.ToArray()) <= teamMax);
List<IntVar> team2Tasks = new List<IntVar>();
foreach (int worker in team2)
{
foreach (int task in allTasks)
{
team2Tasks.Add(x[worker, task]);
}
}
model.Add(LinearExpr.Sum(team2Tasks.ToArray()) <= teamMax);
// Objective
LinearExprBuilder obj = LinearExpr.NewBuilder();
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
obj.AddTerm(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");
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
if (solver.Value(x[worker, task]) > 0.5)
{
Console.WriteLine($"Worker {worker} assigned to task {task}. " +
$"Cost: {costs[worker, task]}");
}
}
}
}
else
{
Console.WriteLine("No solution found.");
}
Console.WriteLine("Statistics");
Console.WriteLine($" - conflicts : {solver.NumConflicts()}");
Console.WriteLine($" - branches : {solver.NumBranches()}");
Console.WriteLine($" - wall time : {solver.WallTime()}s");
}
}
פתרון MIP
בשלב הבא מתארים פתרון לבעיה הזו בהקצאה באמצעות פותר MIP.
ייבוא הספריות
הקוד הבא מייבא את הספרייה הנדרשת.
Python
from ortools.linear_solver import pywraplp
C++
#include <cstdint> #include <memory> #include <numeric> #include <vector> #include "absl/strings/str_format.h" #include "ortools/base/logging.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;
הגדרת הנתונים
הקוד הבא יוצר את הנתונים עבור התוכנה.
Python
costs = [
[90, 76, 75, 70],
[35, 85, 55, 65],
[125, 95, 90, 105],
[45, 110, 95, 115],
[60, 105, 80, 75],
[45, 65, 110, 95],
]
num_workers = len(costs)
num_tasks = len(costs[0])
team1 = [0, 2, 4]
team2 = [1, 3, 5]
# Maximum total of tasks for any team
team_max = 2
C++
const std::vector<std::vector<int64_t>> costs = {{
{{90, 76, 75, 70}},
{{35, 85, 55, 65}},
{{125, 95, 90, 105}},
{{45, 110, 95, 115}},
{{60, 105, 80, 75}},
{{45, 65, 110, 95}},
}};
const int num_workers = costs.size();
std::vector<int> all_workers(num_workers);
std::iota(all_workers.begin(), all_workers.end(), 0);
const int num_tasks = costs[0].size();
std::vector<int> all_tasks(num_tasks);
std::iota(all_tasks.begin(), all_tasks.end(), 0);
const std::vector<int64_t> team1 = {{0, 2, 4}};
const std::vector<int64_t> team2 = {{1, 3, 5}};
// Maximum total of tasks for any team
const int team_max = 2;
Java
double[][] costs = {
{90, 76, 75, 70},
{35, 85, 55, 65},
{125, 95, 90, 105},
{45, 110, 95, 115},
{60, 105, 80, 75},
{45, 65, 110, 95},
};
int numWorkers = costs.length;
int numTasks = costs[0].length;
final int[] allWorkers = IntStream.range(0, numWorkers).toArray();
final int[] allTasks = IntStream.range(0, numTasks).toArray();
final int[] team1 = {0, 2, 4};
final int[] team2 = {1, 3, 5};
// Maximum total of tasks for any team
final int teamMax = 2;
C#
int[,] costs = {
{ 90, 76, 75, 70 }, { 35, 85, 55, 65 }, { 125, 95, 90, 105 },
{ 45, 110, 95, 115 }, { 60, 105, 80, 75 }, { 45, 65, 110, 95 },
};
int numWorkers = costs.GetLength(0);
int numTasks = costs.GetLength(1);
int[] allWorkers = Enumerable.Range(0, numWorkers).ToArray();
int[] allTasks = Enumerable.Range(0, numTasks).ToArray();
int[] team1 = { 0, 2, 4 };
int[] team2 = { 1, 3, 5 };
// Maximum total of tasks for any team
int teamMax = 2;
מצהירים על הפותר
הקוד הבא יוצר את הפותר.
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;
}
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#
Solver solver = Solver.CreateSolver("SCIP");
if (solver is null)
{
return;
}
יצירת המשתנים
הקוד הבא יוצר מערך של משתנים בשביל הבעיה.
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 worker in range(num_workers):
for task in range(num_tasks):
x[worker, task] = solver.BoolVar(f"x[{worker},{task}]")
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 worker : all_workers) {
for (int task : all_tasks) {
x[worker][task] =
solver->MakeBoolVar(absl::StrFormat("x[%d,%d]", worker, task));
}
}
Java
// 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 worker : allWorkers) {
for (int task : allTasks) {
x[worker][task] = solver.makeBoolVar("x[" + worker + "," + task + "]");
}
}
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];
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
x[worker, task] = solver.MakeBoolVar($"x[{worker},{task}]");
}
}
הוספת האילוצים
הקוד הבא יוצר את המגבלות עבור התוכנה.
Python
# Each worker is assigned at most 1 task.
for worker in range(num_workers):
solver.Add(solver.Sum([x[worker, task] for task in range(num_tasks)]) <= 1)
# Each task is assigned to exactly one worker.
for task in range(num_tasks):
solver.Add(solver.Sum([x[worker, task] for worker in range(num_workers)]) == 1)
# Each team takes at most two tasks.
team1_tasks = []
for worker in team1:
for task in range(num_tasks):
team1_tasks.append(x[worker, task])
solver.Add(solver.Sum(team1_tasks) <= team_max)
team2_tasks = []
for worker in team2:
for task in range(num_tasks):
team2_tasks.append(x[worker, task])
solver.Add(solver.Sum(team2_tasks) <= team_max)
C++
// Each worker is assigned to at most one task.
for (int worker : all_workers) {
LinearExpr worker_sum;
for (int task : all_tasks) {
worker_sum += x[worker][task];
}
solver->MakeRowConstraint(worker_sum <= 1.0);
}
// Each task is assigned to exactly one worker.
for (int task : all_tasks) {
LinearExpr task_sum;
for (int worker : all_workers) {
task_sum += x[worker][task];
}
solver->MakeRowConstraint(task_sum == 1.0);
}
// Each team takes at most two tasks.
LinearExpr team1_tasks;
for (int worker : team1) {
for (int task : all_tasks) {
team1_tasks += x[worker][task];
}
}
solver->MakeRowConstraint(team1_tasks <= team_max);
LinearExpr team2_tasks;
for (int worker : team2) {
for (int task : all_tasks) {
team2_tasks += x[worker][task];
}
}
solver->MakeRowConstraint(team2_tasks <= team_max);
Java
// Each worker is assigned to at most one task.
for (int worker : allWorkers) {
MPConstraint constraint = solver.makeConstraint(0, 1, "");
for (int task : allTasks) {
constraint.setCoefficient(x[worker][task], 1);
}
}
// Each task is assigned to exactly one worker.
for (int task : allTasks) {
MPConstraint constraint = solver.makeConstraint(1, 1, "");
for (int worker : allWorkers) {
constraint.setCoefficient(x[worker][task], 1);
}
}
// Each team takes at most two tasks.
MPConstraint team1Tasks = solver.makeConstraint(0, teamMax, "");
for (int worker : team1) {
for (int task : allTasks) {
team1Tasks.setCoefficient(x[worker][task], 1);
}
}
MPConstraint team2Tasks = solver.makeConstraint(0, teamMax, "");
for (int worker : team2) {
for (int task : allTasks) {
team2Tasks.setCoefficient(x[worker][task], 1);
}
}
C#
// Each worker is assigned to at most one task.
foreach (int worker in allWorkers)
{
Constraint constraint = solver.MakeConstraint(0, 1, "");
foreach (int task in allTasks)
{
constraint.SetCoefficient(x[worker, task], 1);
}
}
// Each task is assigned to exactly one worker.
foreach (int task in allTasks)
{
Constraint constraint = solver.MakeConstraint(1, 1, "");
foreach (int worker in allWorkers)
{
constraint.SetCoefficient(x[worker, task], 1);
}
}
// Each team takes at most two tasks.
Constraint team1Tasks = solver.MakeConstraint(0, teamMax, "");
foreach (int worker in team1)
{
foreach (int task in allTasks)
{
team1Tasks.SetCoefficient(x[worker, task], 1);
}
}
Constraint team2Tasks = solver.MakeConstraint(0, teamMax, "");
foreach (int worker in team2)
{
foreach (int task in allTasks)
{
team2Tasks.SetCoefficient(x[worker, task], 1);
}
}
יצירת היעד
הקוד הבא יוצר את פונקציית היעד.
Python
objective_terms = []
for worker in range(num_workers):
for task in range(num_tasks):
objective_terms.append(costs[worker][task] * x[worker, task])
solver.Minimize(solver.Sum(objective_terms))
C++
MPObjective* const objective = solver->MutableObjective();
for (int worker : all_workers) {
for (int task : all_tasks) {
objective->SetCoefficient(x[worker][task], costs[worker][task]);
}
}
objective->SetMinimization();
Java
MPObjective objective = solver.objective();
for (int worker : allWorkers) {
for (int task : allTasks) {
objective.setCoefficient(x[worker][task], costs[worker][task]);
}
}
objective.setMinimization();
C#
Objective objective = solver.Objective();
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
objective.SetCoefficient(x[worker, task], costs[worker, task]);
}
}
objective.SetMinimization();
מזמינים את הפותר
הקוד הבא מפעיל את הפותר ומציג את התוצאות.
Python
print(f"Solving with {solver.SolverVersion()}")
status = solver.Solve()
C++
const MPSolver::ResultStatus result_status = solver->Solve();
Java
MPSolver.ResultStatus resultStatus = solver.solve();
C#
Solver.ResultStatus resultStatus = solver.Solve();
הצגת התוצאות
עכשיו אפשר להדפיס את הפתרון.
Python
if status == pywraplp.Solver.OPTIMAL or status == pywraplp.Solver.FEASIBLE:
print(f"Total cost = {solver.Objective().Value()}\n")
for worker in range(num_workers):
for task in range(num_tasks):
if x[worker, task].solution_value() > 0.5:
print(
f"Worker {worker} assigned to task {task}."
+ f" Cost = {costs[worker][task]}"
)
else:
print("No solution found.")
print(f"Time = {solver.WallTime()} ms")
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 worker : all_workers) {
for (int task : all_tasks) {
// Test if x[i][j] is 0 or 1 (with tolerance for floating point
// arithmetic).
if (x[worker][task]->solution_value() > 0.5) {
LOG(INFO) << "Worker " << worker << " assigned to task " << task
<< ". Cost: " << costs[worker][task];
}
}
}
Java
// 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 worker : allWorkers) {
for (int task : allTasks) {
// Test if x[i][j] is 0 or 1 (with tolerance for floating point
// arithmetic).
if (x[worker][task].solutionValue() > 0.5) {
System.out.println("Worker " + worker + " assigned to task " + task
+ ". Cost: " + costs[worker][task]);
}
}
}
} 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");
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
// Test if x[i, j] is 0 or 1 (with tolerance for floating point
// arithmetic).
if (x[worker, task].SolutionValue() > 0.5)
{
Console.WriteLine($"Worker {worker} assigned to task {task}. Cost: {costs[worker, task]}");
}
}
}
}
else
{
Console.WriteLine("No solution found.");
}
הנה הפלט של התוכנה.
Minimum cost assignment: 250.0 Worker 0 assigned to task 2. Cost = 75 Worker 1 assigned to task 0. Cost = 35 Worker 4 assigned to task 3. Cost = 75 Worker 5 assigned to task 1. Cost = 65 Time = 6 milliseconds
התוכנית כולה
הנה התוכנית כולה.
Python
"""MIP example that solves an assignment problem."""
from ortools.linear_solver import pywraplp
def main():
# Data
costs = [
[90, 76, 75, 70],
[35, 85, 55, 65],
[125, 95, 90, 105],
[45, 110, 95, 115],
[60, 105, 80, 75],
[45, 65, 110, 95],
]
num_workers = len(costs)
num_tasks = len(costs[0])
team1 = [0, 2, 4]
team2 = [1, 3, 5]
# Maximum total of tasks for any team
team_max = 2
# 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 worker in range(num_workers):
for task in range(num_tasks):
x[worker, task] = solver.BoolVar(f"x[{worker},{task}]")
# Constraints
# Each worker is assigned at most 1 task.
for worker in range(num_workers):
solver.Add(solver.Sum([x[worker, task] for task in range(num_tasks)]) <= 1)
# Each task is assigned to exactly one worker.
for task in range(num_tasks):
solver.Add(solver.Sum([x[worker, task] for worker in range(num_workers)]) == 1)
# Each team takes at most two tasks.
team1_tasks = []
for worker in team1:
for task in range(num_tasks):
team1_tasks.append(x[worker, task])
solver.Add(solver.Sum(team1_tasks) <= team_max)
team2_tasks = []
for worker in team2:
for task in range(num_tasks):
team2_tasks.append(x[worker, task])
solver.Add(solver.Sum(team2_tasks) <= team_max)
# Objective
objective_terms = []
for worker in range(num_workers):
for task in range(num_tasks):
objective_terms.append(costs[worker][task] * x[worker, task])
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 worker in range(num_workers):
for task in range(num_tasks):
if x[worker, task].solution_value() > 0.5:
print(
f"Worker {worker} assigned to task {task}."
+ f" Cost = {costs[worker][task]}"
)
else:
print("No solution found.")
print(f"Time = {solver.WallTime()} ms")
if __name__ == "__main__":
main()
C++
// Solve a simple assignment problem.
#include <cstdint>
#include <memory>
#include <numeric>
#include <vector>
#include "absl/strings/str_format.h"
#include "ortools/base/logging.h"
#include "ortools/linear_solver/linear_solver.h"
namespace operations_research {
void AssignmentTeamsMip() {
// Data
const std::vector<std::vector<int64_t>> costs = {{
{{90, 76, 75, 70}},
{{35, 85, 55, 65}},
{{125, 95, 90, 105}},
{{45, 110, 95, 115}},
{{60, 105, 80, 75}},
{{45, 65, 110, 95}},
}};
const int num_workers = costs.size();
std::vector<int> all_workers(num_workers);
std::iota(all_workers.begin(), all_workers.end(), 0);
const int num_tasks = costs[0].size();
std::vector<int> all_tasks(num_tasks);
std::iota(all_tasks.begin(), all_tasks.end(), 0);
const std::vector<int64_t> team1 = {{0, 2, 4}};
const std::vector<int64_t> team2 = {{1, 3, 5}};
// Maximum total of tasks for any team
const int team_max = 2;
// 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 worker : all_workers) {
for (int task : all_tasks) {
x[worker][task] =
solver->MakeBoolVar(absl::StrFormat("x[%d,%d]", worker, task));
}
}
// Constraints
// Each worker is assigned to at most one task.
for (int worker : all_workers) {
LinearExpr worker_sum;
for (int task : all_tasks) {
worker_sum += x[worker][task];
}
solver->MakeRowConstraint(worker_sum <= 1.0);
}
// Each task is assigned to exactly one worker.
for (int task : all_tasks) {
LinearExpr task_sum;
for (int worker : all_workers) {
task_sum += x[worker][task];
}
solver->MakeRowConstraint(task_sum == 1.0);
}
// Each team takes at most two tasks.
LinearExpr team1_tasks;
for (int worker : team1) {
for (int task : all_tasks) {
team1_tasks += x[worker][task];
}
}
solver->MakeRowConstraint(team1_tasks <= team_max);
LinearExpr team2_tasks;
for (int worker : team2) {
for (int task : all_tasks) {
team2_tasks += x[worker][task];
}
}
solver->MakeRowConstraint(team2_tasks <= team_max);
// Objective.
MPObjective* const objective = solver->MutableObjective();
for (int worker : all_workers) {
for (int task : all_tasks) {
objective->SetCoefficient(x[worker][task], costs[worker][task]);
}
}
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 worker : all_workers) {
for (int task : all_tasks) {
// Test if x[i][j] is 0 or 1 (with tolerance for floating point
// arithmetic).
if (x[worker][task]->solution_value() > 0.5) {
LOG(INFO) << "Worker " << worker << " assigned to task " << task
<< ". Cost: " << costs[worker][task];
}
}
}
}
} // namespace operations_research
int main(int argc, char** argv) {
operations_research::AssignmentTeamsMip();
return EXIT_SUCCESS;
}
Java
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;
/** MIP example that solves an assignment problem. */
public class AssignmentTeamsMip {
public static void main(String[] args) {
Loader.loadNativeLibraries();
// Data
double[][] costs = {
{90, 76, 75, 70},
{35, 85, 55, 65},
{125, 95, 90, 105},
{45, 110, 95, 115},
{60, 105, 80, 75},
{45, 65, 110, 95},
};
int numWorkers = costs.length;
int numTasks = costs[0].length;
final int[] allWorkers = IntStream.range(0, numWorkers).toArray();
final int[] allTasks = IntStream.range(0, numTasks).toArray();
final int[] team1 = {0, 2, 4};
final int[] team2 = {1, 3, 5};
// Maximum total of tasks for any team
final int teamMax = 2;
// 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 worker : allWorkers) {
for (int task : allTasks) {
x[worker][task] = solver.makeBoolVar("x[" + worker + "," + task + "]");
}
}
// Constraints
// Each worker is assigned to at most one task.
for (int worker : allWorkers) {
MPConstraint constraint = solver.makeConstraint(0, 1, "");
for (int task : allTasks) {
constraint.setCoefficient(x[worker][task], 1);
}
}
// Each task is assigned to exactly one worker.
for (int task : allTasks) {
MPConstraint constraint = solver.makeConstraint(1, 1, "");
for (int worker : allWorkers) {
constraint.setCoefficient(x[worker][task], 1);
}
}
// Each team takes at most two tasks.
MPConstraint team1Tasks = solver.makeConstraint(0, teamMax, "");
for (int worker : team1) {
for (int task : allTasks) {
team1Tasks.setCoefficient(x[worker][task], 1);
}
}
MPConstraint team2Tasks = solver.makeConstraint(0, teamMax, "");
for (int worker : team2) {
for (int task : allTasks) {
team2Tasks.setCoefficient(x[worker][task], 1);
}
}
// Objective
MPObjective objective = solver.objective();
for (int worker : allWorkers) {
for (int task : allTasks) {
objective.setCoefficient(x[worker][task], costs[worker][task]);
}
}
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 worker : allWorkers) {
for (int task : allTasks) {
// Test if x[i][j] is 0 or 1 (with tolerance for floating point
// arithmetic).
if (x[worker][task].solutionValue() > 0.5) {
System.out.println("Worker " + worker + " assigned to task " + task
+ ". Cost: " + costs[worker][task]);
}
}
}
} else {
System.err.println("No solution found.");
}
}
private AssignmentTeamsMip() {}
}
C#
using System;
using System.Collections.Generic;
using System.Linq;
using Google.OrTools.LinearSolver;
public class AssignmentTeamsMip
{
static void Main()
{
// Data.
int[,] costs = {
{ 90, 76, 75, 70 }, { 35, 85, 55, 65 }, { 125, 95, 90, 105 },
{ 45, 110, 95, 115 }, { 60, 105, 80, 75 }, { 45, 65, 110, 95 },
};
int numWorkers = costs.GetLength(0);
int numTasks = costs.GetLength(1);
int[] allWorkers = Enumerable.Range(0, numWorkers).ToArray();
int[] allTasks = Enumerable.Range(0, numTasks).ToArray();
int[] team1 = { 0, 2, 4 };
int[] team2 = { 1, 3, 5 };
// Maximum total of tasks for any team
int teamMax = 2;
// 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];
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
x[worker, task] = solver.MakeBoolVar($"x[{worker},{task}]");
}
}
// Constraints
// Each worker is assigned to at most one task.
foreach (int worker in allWorkers)
{
Constraint constraint = solver.MakeConstraint(0, 1, "");
foreach (int task in allTasks)
{
constraint.SetCoefficient(x[worker, task], 1);
}
}
// Each task is assigned to exactly one worker.
foreach (int task in allTasks)
{
Constraint constraint = solver.MakeConstraint(1, 1, "");
foreach (int worker in allWorkers)
{
constraint.SetCoefficient(x[worker, task], 1);
}
}
// Each team takes at most two tasks.
Constraint team1Tasks = solver.MakeConstraint(0, teamMax, "");
foreach (int worker in team1)
{
foreach (int task in allTasks)
{
team1Tasks.SetCoefficient(x[worker, task], 1);
}
}
Constraint team2Tasks = solver.MakeConstraint(0, teamMax, "");
foreach (int worker in team2)
{
foreach (int task in allTasks)
{
team2Tasks.SetCoefficient(x[worker, task], 1);
}
}
// Objective
Objective objective = solver.Objective();
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
objective.SetCoefficient(x[worker, task], costs[worker, task]);
}
}
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($"Total cost: {solver.Objective().Value()}\n");
foreach (int worker in allWorkers)
{
foreach (int task in allTasks)
{
// Test if x[i, j] is 0 or 1 (with tolerance for floating point
// arithmetic).
if (x[worker, task].SolutionValue() > 0.5)
{
Console.WriteLine($"Worker {worker} assigned to task {task}. Cost: {costs[worker, task]}");
}
}
}
}
else
{
Console.WriteLine("No solution found.");
}
}
}