Remove Duplicates from Sorted List II (Leetcode)
Problem Description​
Given the head of a sorted linked list, delete all nodes that have duplicate numbers, leaving only distinct numbers from the original list. Return the linked list sorted as well.
Examples​
Example 1​
- Input:
- Output:
Example 2​
- Input:
- Output:
Constraints​
- The number of nodes in the list is in the range [0, 300].
- The list is guaranteed to be sorted in ascending order.
Intuition​
The goal is to remove all elements from a sorted linked list that have duplicate values, ensuring that each element appears only once. We use a dummy node to simplify handling edge cases and traverse the list, removing duplicates as we encounter them.
Approach​
-
Initialization:
- Create a dummy node to handle edge cases where the head itself might be a duplicate.
- Initialize two pointers, prev (starting at dummy) and curr (starting at head).
-
Traversal and Duplicate Removal:
- Traverse the linked list using the curr pointer.
- For each node, check if the current value matches the next node's value.
- If duplicates are detected, use a loop to skip all nodes with that value, deleting them.
- Update the prev pointer's next to point to the first non-duplicate node after the series of duplicates.
- If no duplicates are found, move both prev and curr pointers forward.
-
Completion:
- After the loop, update the head to point to the node after the dummy.
- Delete the dummy node to free memory. Return the updated head of the linked list.
Solution Code​
Python​
class ListNode:
def __init__(self, val=0, next=None):
self.val = val
self.next = next
class Solution:
def deleteDuplicates(self, head: ListNode) -> ListNode:
if not head or not head.next:
return head
dummy = ListNode(0) # Dummy node to handle the case when head is a duplicate
dummy.next = head
prev = dummy
curr = head
while curr and curr.next:
if prev.next.val == curr.next.val:
val = curr.next.val
while curr and curr.val == val:
temp = curr
curr = curr.next
del temp # Marking the node for garbage collection
prev.next = curr
else:
prev = prev.next
curr = curr.next
head = dummy.next # Update head in case it has changed
del dummy # Marking the dummy node for garbage collection
return head
Java​
class ListNode {
int val;
ListNode next;
ListNode() {}
ListNode(int val) { this.val = val; }
ListNode(int val, ListNode next) { this.val = val; this.next = next; }
}
class Solution {
public ListNode deleteDuplicates(ListNode head) {
if (head == null || head.next == null) {
return head;
}
ListNode dummy = new ListNode(0); // Dummy node to handle the case when head is a duplicate
dummy.next = head;
ListNode prev = dummy;
ListNode curr = head;
while (curr != null && curr.next != null) {
if (prev.next.val == curr.next.val) {
int val = curr.next.val;
while (curr != null && curr.val == val) {
ListNode temp = curr;
curr = curr.next;
temp = null; // Marking the node for garbage collection
}
prev.next = curr;
} else {
prev = prev.next;
curr = curr.next;
}
}
head = dummy.next; // Update head in case it has changed
dummy = null; // Marking the dummy node for garbage collection
return head;
}
}
C++​
class Solution {
public:
ListNode* deleteDuplicates(ListNode* head) {
if (head == nullptr || head->next == nullptr) {
return head;
}
ListNode* dummy = new ListNode(0); // Dummy node to handle the case when head is a duplicate
dummy->next = head;
ListNode* prev = dummy;
ListNode* curr = head;
while (curr != nullptr && curr->next != nullptr)
{
if (prev->next->val == curr->next->val)
{
int val = curr->next->val;
while (curr != nullptr && curr->val == val)
{
ListNode* temp = curr;
curr = curr->next;
delete temp;
}
prev->next = curr;
} else {
prev = prev->next;
curr = curr->next;
}
}
head = dummy->next; // Update head in case it has changed
delete dummy; // Delete the dummy node
return head;
}
};
Conclusion​
The provided code effectively removes duplicates from a sorted linked list by iterating through the list and adjusting the pointers accordingly to skip duplicate nodes. It uses a dummy node to handle cases where the head itself is a duplicate and performs the deletion in place without modifying the values within the nodes. The solution has a time complexity of , where n is the number of nodes in the linked list, due to the linear traversal required to identify and remove duplicates. The space complexity is since the algorithm operates in constant space, only using a few pointers and temporary variables regardless of the input size. Overall, this solution offers an efficient and straightforward approach to handling duplicate removal in a sorted linked list.