Dato un elenco singolarmente collegato, l'attività è quella di eliminare il nodo centrale dell'elenco.
- Se l'elenco contiene un numero pari di nodi, ci saranno due nodi medi. In questo caso eliminare il secondo nodo centrale.
- Se l'elenco collegato è costituito da un solo nodo, restituisci null.
Esempio:
q3 mesi
Ingresso: LinkedList: 1-> 2-> 3-> 4-> 5
Produzione: 1-> 2-> 4-> 5
Spiegazione:
Ingresso: LinkedList: 2-> 4-> 6-> 7-> 5-> 1
Produzione: 2-> 4-> 6-> 5-> 1
Spiegazione:
Ingresso: Linkedlist: 7
Produzione:
Tabella del contenuto
- [Approccio ingenuo] Utilizzo del tempo di trasporto a due passaggi - O (n) e O (1)
- [Approccio previsto] Attraversamento a una passe con puntatori lenti e veloci - O (N) Time e O (1) Space
[Approccio ingenuo] Utilizzo del tempo di trasporto a due passaggi - O (n) e O (1)
L'idea di base alla base di questo approccio è prima attraversare l'intero elenco collegato per contare il numero totale di nodi. Una volta che conosciamo il numero totale di nodi, possiamo calcolare la posizione del nodo centrale che è all'indice N/2 (dove n è il numero totale di nodi). Quindi esaminare di nuovo l'elenco collegato, ma questa volta ci fermiamo proprio prima del nodo centrale. Una volta lì modifichiamo il puntatore successivo del nodo prima del nodo centrale in modo che salti sul nodo centrale e punta direttamente al nodo dopo di esso
mouse e tipi di mouse
Di seguito è riportato l'implementazione dell'approccio sopra:
C++
// C++ program to delete middle of a linked list #include
// C program to delete middle of a linked list #include
// Java program to delete middle of a linked list class Node { int data; Node next; Node(int x) { data = x; next = null; } } public class GfG { // Function to delete middle node from linked list. public static Node deleteMid(Node head) { // Edge case: return null if there is only // one node. if (head.next == null) return null; int count = 0; Node p1 = head p2 = head; // First pass count the number of nodes // in the linked list using 'p1'. while (p1 != null) { count++; p1 = p1.next; } // Get the index of the node to be deleted. int middleIndex = count / 2; // Second pass let 'p2' move toward predecessor // of the middle node. for (int i = 0; i < middleIndex - 1; ++i) p2 = p2.next; // Delete the middle node and return 'head'. p2.next = p2.next.next; return head; } public static void printList(Node head) { Node temp = head; while (temp != null) { System.out.print(temp.data + ' -> '); temp = temp.next; } System.out.println('null'); } public static void main(String[] args) { // Create a static hardcoded linked list: // 1 -> 2 -> 3 -> 4 -> 5. Node head = new Node(1); head.next = new Node(2); head.next.next = new Node(3); head.next.next.next = new Node(4); head.next.next.next.next = new Node(5); System.out.print('Original Linked List: '); printList(head); // Delete the middle node. head = deleteMid(head); System.out.print ('Linked List after deleting the middle node: '); printList(head); } }
# Python3 program to delete middle of a linked list class Node: def __init__(self data): self.data = data self.next = None # Function to delete middle node from linked list. def deleteMid(head): # Edge case: return None if there is only # one node. if head.next is None: return None count = 0 p1 = head p2 = head # First pass count the number of nodes # in the linked list using 'p1'. while p1 is not None: count += 1 p1 = p1.next # Get the index of the node to be deleted. middleIndex = count // 2 # Second pass let 'p2' move toward the predecessor # of the middle node. for i in range(middleIndex - 1): p2 = p2.next # Delete the middle node and return 'head'. p2.next = p2.next.next return head def printList(head): temp = head while temp is not None: print(temp.data end=' -> ') temp = temp.next print('None') if __name__ == '__main__': # Create a static hardcoded linked list: # 1 -> 2 -> 3 -> 4 -> 5. head = Node(1) head.next = Node(2) head.next.next = Node(3) head.next.next.next = Node(4) head.next.next.next.next = Node(5) print('Original Linked List:' end=' ') printList(head) # Delete the middle node. head = deleteMid(head) print('Linked List after deleting the middle node:' end=' ') printList(head)
// C# program to delete middle of a linked list using System; class Node { public int data; public Node next; public Node(int x) { data = x; next = null; } } class GfG { // Function to delete middle node from linked list. static Node deleteMid(Node head) { // Edge case: return null if there is only // one node. if (head.next == null) return null; int count = 0; Node p1 = head p2 = head; // First pass count the number of nodes // in the linked list using 'p1'. while (p1 != null) { count++; p1 = p1.next; } // Get the index of the node to be deleted. int middleIndex = count / 2; // Second pass let 'p2' move toward the predecessor // of the middle node. for (int i = 0; i < middleIndex - 1; ++i) p2 = p2.next; // Delete the middle node and return 'head'. p2.next = p2.next.next; return head; } static void printList(Node head) { Node temp = head; while (temp != null) { Console.Write(temp.data + ' -> '); temp = temp.next; } Console.WriteLine('null'); } static void Main(string[] args) { // Create a static hardcoded linked list: // 1 -> 2 -> 3 -> 4 -> 5. Node head = new Node(1); head.next = new Node(2); head.next.next = new Node(3); head.next.next.next = new Node(4); head.next.next.next.next = new Node(5); Console.Write('Original Linked List: '); printList(head); // Delete the middle node. head = deleteMid(head); Console.Write ('Linked List after deleting the middle node: '); printList(head); } }
class Node { constructor(data) { this.data = data; this.next = null; } } // Function to delete middle node from linked list. function deleteMid(head) { // Edge case: return null if there is only // one node. if (head.next === null) return null; let count = 0; let p1 = head p2 = head; // First pass count the number of nodes // in the linked list using 'p1'. while (p1 !== null) { count++; p1 = p1.next; } // Get the index of the node to be deleted. let middleIndex = Math.floor(count / 2); // Second pass let 'p2' move toward the predecessor // of the middle node. for (let i = 0; i < middleIndex - 1; ++i) p2 = p2.next; // Delete the middle node and return 'head'. p2.next = p2.next.next; return head; } function printList(head) { let temp = head; while (temp !== null) { console.log(temp.data + ' -> '); temp = temp.next; } console.log('null'); } // Create a static hardcoded linked list: // 1 -> 2 -> 3 -> 4 -> 5. let head = new Node(1); head.next = new Node(2); head.next.next = new Node(3); head.next.next.next = new Node(4); head.next.next.next.next = new Node(5); console.log('Original Linked List: '); printList(head); // Delete the middle node. head = deleteMid(head); console.log('Linked List after deleting the middle node: '); printList(head);
Produzione
Original Linked List: 1 -> 2 -> 3 -> 4 -> 5 -> nullptr Linked List after deleting the middle node: 1 -> 2 -> 4 -> 5 -> nullptr
Complessità temporale: SU). Sono necessari due traversali dell'elenco collegato
Spazio ausiliario: O (1). Non è necessario uno spazio extra.
[Approccio previsto] Attraversamento a una passe con puntatori lenti e veloci - O (N) Time e O (1) Space
La soluzione sopra richiede due attraversamenti dell'elenco collegato. Il nodo centrale può essere eliminato usando un attraversamento. L'idea è di usare due puntatori slow_ptr E Fast_ptr . Il puntatore veloce sposta due nodi alla volta mentre il puntatore lento muove un nodo alla volta. Quando il puntatore veloce raggiunge la fine dell'elenco, il puntatore lento verrà posizionato sul nodo centrale. Successivamente è necessario collegare il nodo che viene prima del nodo centrale ( prev ) al nodo che viene dopo il nodo centrale. Questo salta efficacemente sul nodo centrale rimuovendolo dall'elenco.
Di seguito è riportata l'implementazione dell'approccio sopra
C++// C++ program to delete middle of a linked list #include
// C program to delete middle of a linked list #include
// Java program to delete the middle of a linked list class Node { int data; Node next; Node(int x) { data = x; next = null; } } class GfG { // Function to delete middle node from linked list static Node deleteMid(Node head) { // If the list is empty return null if (head == null) return null; // If the list has only one node // delete it and return null if (head.next == null) { return null; } Node prev = null; Node slow_ptr = head; Node fast_ptr = head; // Move the fast pointer 2 nodes ahead // and the slow pointer 1 node ahead // until fast pointer reaches end of list while (fast_ptr != null && fast_ptr.next != null) { fast_ptr = fast_ptr.next.next; // Update prev to hold the previous // slow pointer value prev = slow_ptr; slow_ptr = slow_ptr.next; } // At this pointslow_ptr points to middle node // Bypass the middle node prev.next = slow_ptr.next; // Return the head of the modified list return head; } static void printList(Node head) { Node temp = head; while (temp != null) { System.out.print(temp.data + ' -> '); temp = temp.next; } System.out.println('NULL'); } public static void main(String[] args) { // Create a static hardcoded linked list: // 1 -> 2 -> 3 -> 4 -> 5 Node head = new Node(1); head.next = new Node(2); head.next.next = new Node(3); head.next.next.next = new Node(4); head.next.next.next.next = new Node(5); System.out.print('Original Linked List: '); printList(head); // Delete the middle node head = deleteMid(head); System.out.print ('Linked List after deleting the middle node: '); printList(head); } }
# Python program to delete the middle of a linked list class Node: def __init__(self data): self.data = data self.next = None # Function to delete middle node from linked list def deleteMid(head): # If the list is empty return None if head is None: return None # If the list has only one node # delete it and return None if head.next is None: return None prev = None slow_ptr = head fast_ptr = head # Move the fast pointer 2 nodes ahead # and the slow pointer 1 node ahead # until fast pointer reaches end of the list while fast_ptr is not None and fast_ptr.next is not None: fast_ptr = fast_ptr.next.next # Update prev to hold the previous # slow pointer value prev = slow_ptr slow_ptr = slow_ptr.next # At this point slow_ptr points to middle node # Bypass the middle node prev.next = slow_ptr.next # Return the head of the modified list return head def printList(head): temp = head while temp: print(temp.data end=' -> ') temp = temp.next print('NULL') if __name__ == '__main__': # Create a static hardcoded linked list: # 1 -> 2 -> 3 -> 4 -> 5 head = Node(1) head.next = Node(2) head.next.next = Node(3) head.next.next.next = Node(4) head.next.next.next.next = Node(5) print('Original Linked List: ' end='') printList(head) # Delete the middle node head = deleteMid(head) print('Linked List after deleting the middle node: ' end='') printList(head)
// C# program to delete middle of a linked list using System; class Node { public int data; public Node next; public Node(int x) { data = x; next = null; } } class GfG { // Function to delete middle node from linked list public static Node deleteMid(Node head) { // If the list is empty return null if (head == null) return null; // If the list has only one node // delete it and return null if (head.next == null) { return null; } Node prev = null; Node slow_ptr = head; Node fast_ptr = head; // Move the fast pointer 2 nodes ahead // and the slow pointer 1 node ahead // until fast pointer reaches end of the list while (fast_ptr != null && fast_ptr.next != null) { fast_ptr = fast_ptr.next.next; // Update prev to hold the previous // slow pointer value prev = slow_ptr; slow_ptr = slow_ptr.next; } // At this point slow_ptr points to middle node // Bypass the middle node prev.next = slow_ptr.next; // Return the head of the modified list return head; } // Function to print the linked list public static void printList(Node head) { Node temp = head; while (temp != null) { Console.Write(temp.data + ' -> '); temp = temp.next; } Console.WriteLine('NULL'); } public static void Main(string[] args) { // Create a static hardcoded linked list: // 1 -> 2 -> 3 -> 4 -> 5 Node head = new Node(1); head.next = new Node(2); head.next.next = new Node(3); head.next.next.next = new Node(4); head.next.next.next.next = new Node(5); Console.Write('Original Linked List: '); printList(head); // Delete the middle node head = deleteMid(head); Console.Write ('Linked List after deleting the middle node: '); printList(head); } }
// javascript program to delete middle of a linked list class Node { constructor(data) { this.data = data; this.next = null; } } // Function to delete the middle node from the linked list function deleteMid(head) { // If the list is empty return null if (head === null) { return null; } // If the list has only one node delete it and return // null if (head.next === null) { return null; } let prev = null; let slow_ptr = head; let fast_ptr = head; // Move the fast pointer 2 nodes ahead // and the slow pointer 1 node ahead // until the fast pointer reaches the end of the list while (fast_ptr !== null && fast_ptr.next !== null) { fast_ptr = fast_ptr.next.next; // Update prev to hold the previous slow pointer // value prev = slow_ptr; slow_ptr = slow_ptr.next; } // At this point slow_ptr points to the middle node // Bypass the middle node prev.next = slow_ptr.next; // Return the head of the modified list return head; } function printList(head) { let temp = head; while (temp !== null) { process.stdout.write(temp.data + ' -> '); temp = temp.next; } console.log('null'); } // Create a static hardcoded linked list: // 1 -> 2 -> 3 -> 4 -> 5 let head = new Node(1); head.next = new Node(2); head.next.next = new Node(3); head.next.next.next = new Node(4); head.next.next.next.next = new Node(5); process.stdout.write('Original Linked List: '); printList(head); // Delete the middle node head = deleteMid(head); process.stdout.write( 'Linked List after deleting the middle node: '); printList(head);
Produzione
Original Linked List: 1 -> 2 -> 3 -> 4 -> 5 -> NULL Linked List after deleting the middle node: 1 -> 2 -> 4 -> 5 -> NULL
Complessità temporale: SU). È necessario solo un attraversamento dell'elenco collegato
Spazio ausiliario: O (1). Poiché non è necessario uno spazio extra.
Articolo correlato:
- Trova il centro dell'elenco collegato