Dada una lista enlazada donde, además del puntero siguiente, cada Node tiene un puntero secundario, que puede o no apuntar a una lista separada. Estas listas de elementos secundarios pueden tener uno o más elementos secundarios propios, y así sucesivamente, para producir una estructura de datos de varios niveles, como se muestra en la siguiente figura. Se le asigna el encabezado del primer nivel de la lista. Aplane la lista para que todos los Nodes aparezcan en una lista vinculada de un solo nivel. Debe aplanar la lista de manera que todos los Nodes del primer nivel estén primero, luego los Nodes del segundo nivel, y así sucesivamente.
Cada Node es una estructura C con la siguiente definición.
C
struct List { int data; struct List *next; struct List *child; };
C++
class List{ public: int data; List *next; List *child; }; // This code is contributed by lokeshmvs21.
Java
static class List { public int data; public List next; public List child; }; // This code is contributed by pratham76
Python3
# A linked list node has data, # next pointer and child pointer class Node: def __init__(self, data): self.data = data self.next = None self.child = None # This code contributed by umadevi9616
C#
static class List { public int data; public List next; public List child; }; // This code is contributed by rutvik_56
Javascript
<script> class List { constructor(){ this.data = 0; this.next = null; this.child = null; } } // This code contributed by aashish1995 </script>
La lista anterior debe convertirse a 10->5->12->7->11->4->20->13->17->6->2->16->9->8->3 ->19->15
El problema dice claramente que necesitamos aplanar nivel por nivel. La idea de la solución es que comenzamos desde el primer nivel, procesamos todos los Nodes uno por uno, si un Node tiene un hijo, luego agregamos el hijo al final de la lista, de lo contrario no hacemos nada. Después de procesar el primer nivel, todos los Nodes del siguiente nivel se agregarán después del primer nivel. Se sigue el mismo proceso para los Nodes adjuntos.
1) Take "cur" pointer, which will point to head of the first level of the list 2) Take "tail" pointer, which will point to end of the first level of the list 3) Repeat the below procedure while "curr" is not NULL. I) if current node has a child then a) append this new child list to the "tail" tail->next = cur->child b) find the last node of new child list and update "tail" tmp = cur->child; while (tmp->next != NULL) tmp = tmp->next; tail = tmp; II) move to the next node. i.e. cur = cur->next
A continuación se muestra la implementación del algoritmo anterior.
C++
// C++ Program to flatten list with // next and child pointers #include <bits/stdc++.h> using namespace std; // Macro to find number of elements in array #define SIZE(arr) (sizeof(arr)/sizeof(arr[0])) // A linked list node has data, // next pointer and child pointer class Node { public: int data; Node *next; Node *child; }; // A utility function to create a linked list // with n nodes. The data of nodes is taken // from arr[]. All child pointers are set as NULL Node *createList(int *arr, int n) { Node *head = NULL; Node *p; int i; for (i = 0; i < n; ++i) { if (head == NULL) head = p = new Node(); else { p->next = new Node(); p = p->next; } p->data = arr[i]; p->next = p->child = NULL; } return head; } // A utility function to print // all nodes of a linked list void printList(Node *head) { while (head != NULL) { cout << head->data << " "; head = head->next; } cout<<endl; } // This function creates the input // list. The created list is same // as shown in the above figure Node *createList(void) { int arr1[] = {10, 5, 12, 7, 11}; int arr2[] = {4, 20, 13}; int arr3[] = {17, 6}; int arr4[] = {9, 8}; int arr5[] = {19, 15}; int arr6[] = {2}; int arr7[] = {16}; int arr8[] = {3}; /* create 8 linked lists */ Node *head1 = createList(arr1, SIZE(arr1)); Node *head2 = createList(arr2, SIZE(arr2)); Node *head3 = createList(arr3, SIZE(arr3)); Node *head4 = createList(arr4, SIZE(arr4)); Node *head5 = createList(arr5, SIZE(arr5)); Node *head6 = createList(arr6, SIZE(arr6)); Node *head7 = createList(arr7, SIZE(arr7)); Node *head8 = createList(arr8, SIZE(arr8)); /* modify child pointers to create the list shown above */ head1->child = head2; head1->next->next->next->child = head3; head3->child = head4; head4->child = head5; head2->next->child = head6; head2->next->next->child = head7; head7->child = head8; /* Return head pointer of first linked list. Note that all nodes are reachable from head1 */ return head1; } /* The main function that flattens a multilevel linked list */ void flattenList(Node *head) { /*Base case*/ if (head == NULL) return; Node *tmp; /* Find tail node of first level linked list */ Node *tail = head; while (tail->next != NULL) tail = tail->next; // One by one traverse through all nodes of first level // linked list till we reach the tail node Node *cur = head; while (cur != tail) { // If current node has a child if (cur->child) { // then append the child at the end of current list tail->next = cur->child; // and update the tail to new last node tmp = cur->child; while (tmp->next) tmp = tmp->next; tail = tmp; } // Change current node cur = cur->next; } } // Driver code int main(void) { Node *head = NULL; head = createList(); flattenList(head); printList(head); return 0; } // This code is contributed by rathbhupendra
C
// Program to flatten list with next and child pointers #include <stdio.h> #include <stdlib.h> // Macro to find number of elements in array #define SIZE(arr) (sizeof(arr)/sizeof(arr[0])) // A linked list node has data, next pointer and child pointer struct Node { int data; struct Node *next; struct Node *child; }; // A utility function to create a linked list with n nodes. The data // of nodes is taken from arr[]. All child pointers are set as NULL struct Node *createList(int *arr, int n) { struct Node *head = NULL; struct Node *p; int i; for (i = 0; i < n; ++i) { if (head == NULL) head = p = (struct Node *)malloc(sizeof(*p)); else { p->next = (struct Node *)malloc(sizeof(*p)); p = p->next; } p->data = arr[i]; p->next = p->child = NULL; } return head; } // A utility function to print all nodes of a linked list void printList(struct Node *head) { while (head != NULL) { printf("%d ", head->data); head = head->next; } printf("\n"); } // This function creates the input list. The created list is same // as shown in the above figure struct Node *createList(void) { int arr1[] = {10, 5, 12, 7, 11}; int arr2[] = {4, 20, 13}; int arr3[] = {17, 6}; int arr4[] = {9, 8}; int arr5[] = {19, 15}; int arr6[] = {2}; int arr7[] = {16}; int arr8[] = {3}; /* create 8 linked lists */ struct Node *head1 = createList(arr1, SIZE(arr1)); struct Node *head2 = createList(arr2, SIZE(arr2)); struct Node *head3 = createList(arr3, SIZE(arr3)); struct Node *head4 = createList(arr4, SIZE(arr4)); struct Node *head5 = createList(arr5, SIZE(arr5)); struct Node *head6 = createList(arr6, SIZE(arr6)); struct Node *head7 = createList(arr7, SIZE(arr7)); struct Node *head8 = createList(arr8, SIZE(arr8)); /* modify child pointers to create the list shown above */ head1->child = head2; head1->next->next->next->child = head3; head3->child = head4; head4->child = head5; head2->next->child = head6; head2->next->next->child = head7; head7->child = head8; /* Return head pointer of first linked list. Note that all nodes are reachable from head1 */ return head1; } /* The main function that flattens a multilevel linked list */ void flattenList(struct Node *head) { /*Base case*/ if (head == NULL) return; struct Node *tmp; /* Find tail node of first level linked list */ struct Node *tail = head; while (tail->next != NULL) tail = tail->next; // One by one traverse through all nodes of first level // linked list till we reach the tail node struct Node *cur = head; while (cur != tail) { // If current node has a child if (cur->child) { // then append the child at the end of current list tail->next = cur->child; // and update the tail to new last node tmp = cur->child; while (tmp->next) tmp = tmp->next; tail = tmp; } // Change current node cur = cur->next; } } // A driver program to test above functions int main(void) { struct Node *head = NULL; head = createList(); flattenList(head); printList(head); return 0; }
Java
// Java program to flatten linked list with next and child pointers class LinkedList { static Node head; class Node { int data; Node next, child; Node(int d) { data = d; next = child = null; } } // A utility function to create a linked list with n nodes. The data // of nodes is taken from arr[]. All child pointers are set as NULL Node createList(int arr[], int n) { Node node = null; Node p = null; int i; for (i = 0; i < n; ++i) { if (node == null) { node = p = new Node(arr[i]); } else { p.next = new Node(arr[i]); p = p.next; } p.next = p.child = null; } return node; } // A utility function to print all nodes of a linked list void printList(Node node) { while (node != null) { System.out.print(node.data + " "); node = node.next; } System.out.println(""); } Node createList() { int arr1[] = new int[]{10, 5, 12, 7, 11}; int arr2[] = new int[]{4, 20, 13}; int arr3[] = new int[]{17, 6}; int arr4[] = new int[]{9, 8}; int arr5[] = new int[]{19, 15}; int arr6[] = new int[]{2}; int arr7[] = new int[]{16}; int arr8[] = new int[]{3}; /* create 8 linked lists */ Node head1 = createList(arr1, arr1.length); Node head2 = createList(arr2, arr2.length); Node head3 = createList(arr3, arr3.length); Node head4 = createList(arr4, arr4.length); Node head5 = createList(arr5, arr5.length); Node head6 = createList(arr6, arr6.length); Node head7 = createList(arr7, arr7.length); Node head8 = createList(arr8, arr8.length); /* modify child pointers to create the list shown above */ head1.child = head2; head1.next.next.next.child = head3; head3.child = head4; head4.child = head5; head2.next.child = head6; head2.next.next.child = head7; head7.child = head8; /* Return head pointer of first linked list. Note that all nodes are reachable from head1 */ return head1; } /* The main function that flattens a multilevel linked list */ void flattenList(Node node) { /*Base case*/ if (node == null) { return; } Node tmp = null; /* Find tail node of first level linked list */ Node tail = node; while (tail.next != null) { tail = tail.next; } // One by one traverse through all nodes of first level // linked list till we reach the tail node Node cur = node; while (cur != tail) { // If current node has a child if (cur.child != null) { // then append the child at the end of current list tail.next = cur.child; // and update the tail to new last node tmp = cur.child; while (tmp.next != null) { tmp = tmp.next; } tail = tmp; } // Change current node cur = cur.next; } } public static void main(String[] args) { LinkedList list = new LinkedList(); head = list.createList(); list.flattenList(head); list.printList(head); } } // This code has been contributed by Mayank Jaiswal
Python3
# Python3 Program to flatten list with # next and child pointers # A linked list node has data, # next pointer and child pointer class Node: def __init__(self, data): self.data = data self.next = None self.child = None # Return Node def newNode(data): return Node(data) # The main function that flattens # a multilevel linked list def flattenlist(head): # Base case if not head: return # Find tail node of first level linked list temp = head while(temp.next != None): temp = temp.next currNode = head # One by one traverse through all nodes # of first level linked list # till we reach the tail node while(currNode != temp): # If current node has a child if(currNode.child): # then append the child # at the end of current list temp.next = currNode.child # and update the tail to new last node tmp = currNode.child while(tmp.next): tmp = tmp.next temp = tmp # Change current node currNode = currNode.next # A utility function to print # all nodes of a linked list def printList(head): if not head: return while(head): print("{}".format(head.data), end = " ") head = head.next # Driver code if __name__=='__main__': # Child list of 13 child13 = newNode(16) child13.child = newNode(3) # Child List of 10 head1 = newNode(4) head1.next = newNode(20) head1.next.child = newNode(2) #Child of 20 head1.next.next = newNode(13) head1.next.next.child = child13 # Child of 9 child9 = newNode(19) child9.next = newNode(15) # Child List of 17 child17 = newNode(9) child17.next = newNode(8) child17.child = child9 # Child List of 7 head2 = newNode(17) head2.next = newNode(6) head2.child = child17 # Main List head = newNode(10) head.child = head1 head.next = newNode(5) head.next.next = newNode(12) head.next.next.next = newNode(7) head.next.next.next.child = head2 head.next.next.next.next = newNode(11) flattenlist(head) print("\Flattened list is: ", end = "") printList(head) # This code is contributed by 0_hero
C#
// C# program to flatten linked list // with next and child pointers using System; public class LinkedList { static Node head; class Node { public int data; public Node next, child; public Node(int d) { data = d; next = child = null; } } // A utility function to create // a linked list with n nodes. The data // of nodes is taken from arr[]. // All child pointers are set as NULL Node createList(int []arr, int n) { Node node = null; Node p = null; int i; for (i = 0; i < n; ++i) { if (node == null) { node = p = new Node(arr[i]); } else { p.next = new Node(arr[i]); p = p.next; } p.next = p.child = null; } return node; } // A utility function to print // all nodes of a linked list void printList(Node node) { while (node != null) { Console.Write(node.data + " "); node = node.next; } Console.WriteLine(""); } Node createList() { int []arr1 = new int[]{10, 5, 12, 7, 11}; int []arr2 = new int[]{4, 20, 13}; int []arr3 = new int[]{17, 6}; int []arr4 = new int[]{9, 8}; int []arr5 = new int[]{19, 15}; int []arr6 = new int[]{2}; int []arr7 = new int[]{16}; int []arr8 = new int[]{3}; /* create 8 linked lists */ Node head1 = createList(arr1, arr1.Length); Node head2 = createList(arr2, arr2.Length); Node head3 = createList(arr3, arr3.Length); Node head4 = createList(arr4, arr4.Length); Node head5 = createList(arr5, arr5.Length); Node head6 = createList(arr6, arr6.Length); Node head7 = createList(arr7, arr7.Length); Node head8 = createList(arr8, arr8.Length); /* modify child pointers to create the list shown above */ head1.child = head2; head1.next.next.next.child = head3; head3.child = head4; head4.child = head5; head2.next.child = head6; head2.next.next.child = head7; head7.child = head8; /* Return head pointer of first linked list. Note that all nodes are reachable from head1 */ return head1; } /* The main function that flattens a multilevel linked list */ void flattenList(Node node) { /*Base case*/ if (node == null) { return; } Node tmp = null; /* Find tail node of first level linked list */ Node tail = node; while (tail.next != null) { tail = tail.next; } // One by one traverse through // all nodes of first level // linked list till we reach the tail node Node cur = node; while (cur != tail) { // If current node has a child if (cur.child != null) { // then append the child at // the end of current list tail.next = cur.child; // and update the tail to new last node tmp = cur.child; while (tmp.next != null) { tmp = tmp.next; } tail = tmp; } // Change current node cur = cur.next; } } // Driver code public static void Main() { LinkedList list = new LinkedList(); head = list.createList(); list.flattenList(head); list.printList(head); } } /* This code is contributed PrinciRaj1992 */
10 5 12 7 11 4 20 13 17 6 2 16 9 8 3 19 15
Complejidad de tiempo: dado que cada Node se visita como máximo dos veces, la complejidad de tiempo es O (n), donde n es el número de Nodes en una lista vinculada dada.
Publicación traducida automáticamente
Artículo escrito por GeeksforGeeks-1 y traducido por Barcelona Geeks. The original can be accessed here. Licence: CCBY-SA