Dados N trabajos donde cada trabajo está representado por los siguientes tres elementos.
1. Hora de inicio
2. Hora de finalización
3. Beneficio o valor asociado
Encuentre el subconjunto de trabajos con ganancias máximas de modo que no se superpongan dos trabajos en el subconjunto.
Ejemplos:
Input:
Number of Jobs n = 4
Job Details {Start Time Finish Time Profit}
Job 1: {1 2 50}
Job 2: {3 5 20}
Job 3: {6 19 100}
Job 4: {2 100 200}
Output:
Job 1: {1 2 50}
Job 4: {2 100 200}
Explanation: We can get the maximum profit by
scheduling jobs 1 and 4 and maximum profit is 250.
En anterior publicación que hemos discutido sobre el problema de programación de trabajos ponderados. Discutimos una solución de DP en la que básicamente incluimos o excluimos el trabajo actual. En esta publicación se analiza otra solución DP interesante donde también imprimimos los trabajos. Este problema es una variación del estándar. Subsecuencia creciente más larga (LIS) problema. Necesitamos un ligero cambio en la solución de programación dinámica del problema LIS.
Primero debemos ordenar los trabajos según la hora de inicio. Sea job[0..n-1] la matriz de trabajos después de la clasificación. Definimos el vector L tal que L[i] es en sí mismo un vector que almacena la programación de trabajos ponderados del trabajo[0..i] que termina con el trabajo[i]. Por lo tanto, para un índice i, L[i] se puede escribir de forma recursiva como:
L[0] = {job[0]}
L[i] = {MaxSum(L[j])} + job[i] where j < i and job[j].finish <= job[i].start
= job[i] if there is no such j
Por ejemplo, considere los pares {3 10 20} {1 2 50} {6 19 100} {2 100 200}
After sorting we get
{1 2 50} {2 100 200} {3 10 20} {6 19 100}
Therefore
L[0]: {1 2 50}
L[1]: {1 2 50} {2 100 200}
L[2]: {1 2 50} {3 10 20}
L[3]: {1 2 50} {6 19 100}
Elegimos el vector con mayor beneficio. En este caso L[1].
A continuación se muestra la implementación de la idea anterior:
C++// C++ program for weighted job scheduling using LIS #include
// Java program for weighted job // scheduling using LIS import java.util.ArrayList; import java.util.Arrays; import java.util.Collections; import java.util.Comparator; class Graph{ // A job has start time finish time // and profit. static class Job { int start finish profit; public Job(int start int finish int profit) { this.start = start; this.finish = finish; this.profit = profit; } }; // Utility function to calculate sum of all // ArrayList elements static int findSum(ArrayList<Job> arr) { int sum = 0; for(int i = 0; i < arr.size(); i++) sum += arr.get(i).profit; return sum; } // The main function that finds the maximum // possible profit from given array of jobs static void findMaxProfit(ArrayList<Job> arr) { // Sort arr[] by start time. Collections.sort(arr new Comparator<Job>() { @Override public int compare(Job x Job y) { return x.start - y.start; } }); // sort(arr.begin() arr.end() compare); // L[i] stores Weighted Job Scheduling of // job[0..i] that ends with job[i] ArrayList<ArrayList<Job>> L = new ArrayList<>(); for(int i = 0; i < arr.size(); i++) { L.add(new ArrayList<>()); } // L[0] is equal to arr[0] L.get(0).add(arr.get(0)); // Start from index 1 for(int i = 1; i < arr.size(); i++) { // For every j less than i for(int j = 0; j < i; j++) { // L[i] = {MaxSum(L[j])} + arr[i] where j < i // and arr[j].finish <= arr[i].start if ((arr.get(j).finish <= arr.get(i).start) && (findSum(L.get(j)) > findSum(L.get(i)))) { ArrayList<Job> copied = new ArrayList<>( L.get(j)); L.set(i copied); } } L.get(i).add(arr.get(i)); } ArrayList<Job> maxChain = new ArrayList<>(); // Find one with max profit for(int i = 0; i < L.size(); i++) if (findSum(L.get(i)) > findSum(maxChain)) maxChain = L.get(i); for(int i = 0; i < maxChain.size(); i++) { System.out.printf('(%d %d %d)n' maxChain.get(i).start maxChain.get(i).finish maxChain.get(i).profit); } } // Driver code public static void main(String[] args) { Job[] a = { new Job(3 10 20) new Job(1 2 50) new Job(6 19 100) new Job(2 100 200) }; ArrayList<Job> arr = new ArrayList<>( Arrays.asList(a)); findMaxProfit(arr); } } // This code is contributed by sanjeev2552
# Python program for weighted job scheduling using LIS import sys # A job has start time finish time and profit. class Job: def __init__(self start finish profit): self.start = start self.finish = finish self.profit = profit # Utility function to calculate sum of all vector elements def findSum(arr): sum = 0 for i in range(len(arr)): sum += arr[i].profit return sum # comparator function for sort function def compare(x y): if x.start < y.start: return -1 elif x.start == y.start: return 0 else: return 1 # The main function that finds the maximum possible profit from given array of jobs def findMaxProfit(arr): # Sort arr[] by start time. arr.sort(key=lambda x: x.start) # L[i] stores Weighted Job Scheduling of job[0..i] that ends with job[i] L = [[] for _ in range(len(arr))] # L[0] is equal to arr[0] L[0].append(arr[0]) # start from index 1 for i in range(1 len(arr)): # for every j less than i for j in range(i): # L[i] = {MaxSum(L[j])} + arr[i] where j < i # and arr[j].finish <= arr[i].start if arr[j].finish <= arr[i].start and findSum(L[j]) > findSum(L[i]): L[i] = L[j][:] L[i].append(arr[i]) maxChain = [] # find one with max profit for i in range(len(L)): if findSum(L[i]) > findSum(maxChain): maxChain = L[i] for i in range(len(maxChain)): print('({} {} {})'.format( maxChain[i].start maxChain[i].finish maxChain[i].profit) end=' ') # Driver Function if __name__ == '__main__': a = [Job(3 10 20) Job(1 2 50) Job(6 19 100) Job(2 100 200)] findMaxProfit(a)
using System; using System.Collections.Generic; using System.Linq; public class Graph { // A job has start time finish time // and profit. public class Job { public int start finish profit; public Job(int start int finish int profit) { this.start = start; this.finish = finish; this.profit = profit; } }; // Utility function to calculate sum of all // ArrayList elements public static int FindSum(List<Job> arr) { int sum = 0; for(int i = 0; i < arr.Count; i++) sum += arr.ElementAt(i).profit; return sum; } // The main function that finds the maximum // possible profit from given array of jobs public static void FindMaxProfit(List<Job> arr) { // Sort arr[] by start time. arr.Sort((x y) => x.start.CompareTo(y.start)); // L[i] stores Weighted Job Scheduling of // job[0..i] that ends with job[i] List<List<Job>> L = new List<List<Job>>(); for(int i = 0; i < arr.Count; i++) { L.Add(new List<Job>()); } // L[0] is equal to arr[0] L[0].Add(arr[0]); // Start from index 1 for(int i = 1; i < arr.Count; i++) { // For every j less than i for(int j = 0; j < i; j++) { // L[i] = {MaxSum(L[j])} + arr[i] where j < i // and arr[j].finish <= arr[i].start if ((arr[j].finish <= arr[i].start) && (FindSum(L[j]) > FindSum(L[i]))) { List<Job> copied = new List<Job>( L[j]); L[i] = copied; } } L[i].Add(arr[i]); } List<Job> maxChain = new List<Job>(); // Find one with max profit for(int i = 0; i < L.Count; i++) if (FindSum(L[i]) > FindSum(maxChain)) maxChain = L[i]; for(int i = 0; i < maxChain.Count; i++) { Console.WriteLine('({0} {1} {2})' maxChain[i].start maxChain[i].finish maxChain[i].profit); } } // Driver code public static void Main(String[] args) { Job[] a = { new Job(3 10 20) new Job(1 2 50) new Job(6 19 100) new Job(2 100 200) }; List<Job> arr = new List<Job>(a); FindMaxProfit(arr); } }
// JavaScript program for weighted job scheduling using LIS // A job has start time finish time and profit. function Job(start finish profit) { this.start = start; this.finish = finish; this.profit = profit; } // Utility function to calculate sum of all vector // elements function findSum(arr) { let sum = 0; for (let i = 0; i < arr.length; i++) { sum += arr[i].profit; } return sum; } // comparator function for sort function function compare(x y) { return x.start < y.start; } // The main function that finds the maximum possible // profit from given array of jobs function findMaxProfit(arr) { // Sort arr[] by start time. arr.sort(compare); // L[i] stores Weighted Job Scheduling of // job[0..i] that ends with job[i] let L = new Array(arr.length).fill([]); // L[0] is equal to arr[0] L[0] = [arr[0]]; // start from index 1 for (let i = 1; i < arr.length; i++) { // for every j less than i for (let j = 0; j < i; j++) { // L[i] = {MaxSum(L[j])} + arr[i] where j < i // and arr[j].finish <= arr[i].start if (arr[j].finish <= arr[i].start && findSum(L[j]) > findSum(L[i])) { L[i] = L[j]; } } L[i].push(arr[i]); } let maxChain = []; // find one with max profit for (let i = 0; i < L.length; i++) { if (findSum(L[i]) > findSum(maxChain)) { maxChain = L[i]; } } for (let i = 0; i < maxChain.length; i++) { console.log( '(' + maxChain[i].start + ' ' + maxChain[i].finish + ' ' + maxChain[i].profit + ') ' ); } } // Driver Function let a = [ new Job(3 10 20) new Job(1 2 50) new Job(2 100 200) ]; findMaxProfit(a);
Producción
(1 2 50) (2 100 200)
Podemos optimizar aún más la solución DP anterior eliminando la función findSum(). En su lugar, podemos mantener otro vector/matriz para almacenar la suma del máximo beneficio posible hasta el trabajo i.
Complejidad del tiempo de la solución de programación dinámica anterior es O (n2) donde n es el número de trabajos.
Espacio auxiliar utilizado por el programa es O(n2).