1474. Delete N Nodes After M Nodes of a Linked List
Problem Description
In this problem, you are given a singly linked list and two integers m
and n
. The task is to modify the linked list by iterating through it and alternating between keeping and removing nodes. To be precise, you have to keep the first m
nodes, then remove the next n
nodes, and continue this pattern until the end of the list. The outcome should be the head of the linked list after these operations have been performed.
Intuition
The intuition behind the solution is to effectively use two pointers to traverse the linked list: one to mark the boundary of the nodes that will be retained (pre
) and the other to find the boundary where the removal will stop (cur
). The general approach is:
- Keep a pointer to the current node we're looking at, starting with the head of the list.
- Move this pointer
m-1
times forward (since we want to keepm
nodes, we movem-1
times to stay on the last node that we want to keep). - Establish another pointer at the same position and move it
n
times forward to find the last node that we want to remove. - Connect the
m
th node to the node right after the last removed node (effectively skipping overn
nodes). - Continue this process until we reach the end of the list.
This algorithm is an in-place transformation which means we modify the original linked list without using extra space for another list.
Learn more about Linked List patterns.
Solution Approach
The solution to this problem follows a straightforward iterative approach, using a simple while loop to traverse the linked list, removing unwanted nodes as it goes. Below are the steps involved in the implementation:
-
Initialize a pointer named
pre
to point to the head of the list. This pointer will be used to track the node after which node deletion will start. -
Use a while loop that continues until
pre
is notNone
(meaning we have not reached the end of the list). -
Within the while loop, process keeping
m
nodes intact by iteratingm-1
times with a for loop. The-1
is used because we are starting from the nodepre
which is already considered the first of them
nodes. If during this processpre
becomesNone
, we exit the loop because we've reached the end of the list. -
Now, we need a second pointer called
cur
which will start at the same position aspre
and moven
times forward to mark the count of nodes to be deleted. -
After the for loop to remove
n
nodes, setpre.next
tocur.next
, this effectively skips overn
nodes that are to be deleted. Ifcur
isNone
at the end of the for loop, it means we reached the end of the list, and thus, we can safely setpre.next
toNone
. -
Finally, move
pre
topre.next
to process the next batch of nodes, beginning the m-n cycle again.
This solution employs no additional data structures, effectively making it an in-place operation with O(1)
additional space complexity. The time complexity is O(L)
where L
is the number of nodes in the linked list, as each node is visited at most once.
The pattern used is the two-pointer technique, where one pointer (pre
) is used to keep track of the node at the border between kept and removed nodes, and the other (cur
) used to find the next node that pre
should point to after removing n
nodes.
A side note is that we have to manage the case when we reach the end of the list correctly. If cur
becomes None
after the removal loop, it means that we do not have any more nodes to process, and we should break out of the loop.
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Start EvaluatorExample Walkthrough
Let's consider a linked list and use a small example to illustrate the solution approach. Suppose our linked list is 1 -> 2 -> 3 -> 4 -> 5 -> 6 -> 7 -> 8
and the integers m
and n
are given as m = 2
and n = 3
. This means we want to keep 2 nodes and then remove the next 3 nodes, repeating this process until the end of the list.
-
Start with the head of the list. The list is
1 -> 2 -> 3 -> 4 -> 5 -> 6 -> 7 -> 8
. -
The pointer
pre
starts at the head node1
. We iteratem-1
times forward, which in this case is1
time (since we are keeping two nodes,1
and2
). -
Now
pre
is at node2
. Next, we set upcur
to point to the same node aspre
. -
We then move
cur
n
times forward. Sincen
is3
, we movecur
to node5
. -
The list now looks like this, where the brackets indicate the nodes that will remain:
[1 -> 2] 3 -> 4 -> 5 -> 6 -> 7 -> 8
. -
We connect the node at
pre
(which is node2
) tocur.next
(which is node6
). Our list is now1 -> 2 -> 6 -> 7 -> 8
. -
Now, we move
pre
topre.next
which points to node6
. Then we repeat our process. Since there are fewer thanm
nodes left afterpre
, we do not continue and our final output is the list1 -> 2 -> 6 -> 7 -> 8
.
Here are the steps in detail:
-
Initialization:
pre
points to1
, and the list is1 -> 2 -> 3 -> 4 -> 5 -> 6 -> 7 -> 8
. -
Iteration 1:
- Keep
m
nodes:pre
traverses1
node and still points to2
. - Remove
n
nodes:cur
starts at2
and traverses3
nodes, ending up at5
. - Skip
n
nodes: Connect2
to6
. - The list is now
[1 -> 2] -> 6 -> 7 -> 8
.
- Keep
-
Move
pre
topre.next
:pre
now points to6
. -
Iteration 2:
- Since there are fewer than
m
nodes left afterpre
, and we cannot remove more nodes, the process stops.
- Since there are fewer than
The final list, after the in-place modifications, is 1 -> 2 -> 6 -> 7 -> 8
.
Solution Implementation
1# Definition for singly-linked list.
2# class ListNode:
3# def __init__(self, val=0, next=None):
4# self.val = val
5# self.next = next
6
7class Solution:
8 def deleteNodes(self, head: ListNode, m: int, n: int) -> ListNode:
9 current_node = head
10
11 # Iterate over the entire linked list
12 while current_node:
13 # Skip m nodes, these nodes will be retained
14 for _ in range(m - 1):
15 if current_node:
16 current_node = current_node.next
17 # If we reach the end of the list, return the head as we don't have
18 # more nodes to delete
19 if current_node is None:
20 return head
21
22 # Now current_node points to the last node before the deletion begins
23 to_delete = current_node.next
24
25 # Skip n nodes to find the last node which needs to be deleted
26 for _ in range(n):
27 if to_delete:
28 to_delete = to_delete.next
29
30 # Connect the current_node to the node following the last deleted node
31 current_node.next = to_delete
32
33 # Move to the next set of nodes
34 current_node = to_delete
35
36 return head # Return the modified list
37
1class Solution {
2
3 /**
4 * Given a linked list, its head, and two integers m and n,
5 * this function deletes every n nodes in the list after keeping m nodes.
6 *
7 * @param head The head of the singly-linked list.
8 * @param m The number of nodes to keep before deletion starts.
9 * @param n The number of nodes to delete.
10 * @return The head of the modified list.
11 */
12 public ListNode deleteNodes(ListNode head, int m, int n) {
13 // 'currentNode' is used to traverse the linked list starting from the head.
14 ListNode currentNode = head;
15
16 // Continue loop until 'currentNode' is null, which means end of the list.
17 while (currentNode != null) {
18 // Skip 'm' nodes but stop if the end of the list is reached.
19 for (int i = 0; i < m - 1 && currentNode != null; ++i) {
20 currentNode = currentNode.next;
21 }
22
23 // If 'currentNode' is null after the for loop, we return the head
24 // as we reached the end of the list and cannot delete further nodes.
25 if (currentNode == null) {
26 return head;
27 }
28
29 // 'nodeToBeDeleted' points to the node from where we start deletion.
30 ListNode nodeToBeDeleted = currentNode;
31
32 // Advance 'nodeToBeDeleted' 'n' times or until the end of the list is reached.
33 for (int i = 0; i < n && nodeToBeDeleted != null; ++i) {
34 nodeToBeDeleted = nodeToBeDeleted.next;
35 }
36
37 // Connect the 'currentNode.next' to the node after the last deleted node.
38 // If 'nodeToBeDeleted' is null, we've reached the end and thus set next to null.
39 currentNode.next = (nodeToBeDeleted == null) ? null : nodeToBeDeleted.next;
40
41 // Move 'currentNode' ahead to process the next chunk of nodes.
42 currentNode = currentNode.next;
43 }
44
45 // Return the head of the modified list.
46 return head;
47 }
48}
49
1/**
2 * Definition for singly-linked list.
3 * struct ListNode {
4 * int val;
5 * ListNode *next;
6 * ListNode() : val(0), next(nullptr) {}
7 * ListNode(int x) : val(x), next(nullptr) {}
8 * ListNode(int x, ListNode *next) : val(x), next(next) {}
9 * };
10 */
11class Solution {
12public:
13 ListNode* deleteNodes(ListNode* head, int m, int n) {
14 // previous_node will point to the last node before the sequence to be deleted
15 ListNode* previous_node = head;
16
17 // Continue iterating through the linked list until we reach the end
18 while (previous_node) {
19 // Skip m nodes, but retain the last one before deletion begins
20 for (int i = 0; i < m - 1 && previous_node; ++i) {
21 previous_node = previous_node->next;
22 }
23
24 // If we've reached the end, return the head as no deletion is needed
25 if (!previous_node) {
26 return head;
27 }
28
29 // Skip n nodes starting from previous_node->next for deletion
30 ListNode* current = previous_node;
31 for (int i = 0; i < n && current; ++i) {
32 current = current->next;
33 }
34
35 // Connect the previous_node to the node after the n nodes to be deleted
36 // If current is not nullptr, link to the node after the deleted sequence
37 // If current is nullptr, it means we've reached the end of the list, so we set it to nullptr
38 previous_node->next = (current ? current->next : nullptr);
39
40 // Move the previous_node forward to start a new sequence
41 previous_node = previous_node->next;
42 }
43
44 // Return the head of the modified list
45 return head;
46 }
47};
48
1// Definition for singly-linked list node
2class ListNode {
3 val: number;
4 next: ListNode | null;
5
6 constructor(val: number = 0, next: ListNode | null = null) {
7 this.val = val;
8 this.next = next;
9 }
10}
11
12/**
13 * Deletes nodes in a linked list following a pattern: keep 'm' nodes then delete 'n' nodes, repeating this process.
14 * @param head - The head of the singly-linked list.
15 * @param m - The number of nodes to keep.
16 * @param n - The number of nodes to delete.
17 * @returns The head of the modified linked list.
18 */
19function deleteNodes(head: ListNode | null, m: number, n: number): ListNode | null {
20 // previousNode will point to the last node before the sequence to be deleted
21 let previousNode: ListNode | null = head;
22
23 // Continue iterating through the linked list until the end is reached
24 while (previousNode) {
25 // Skip 'm' nodes, but retain the last one before deletion begins
26 for (let i = 0; i < m - 1 && previousNode; i++) {
27 previousNode = previousNode.next;
28 }
29
30 // If the end is reached, no further deletion is needed
31 if (!previousNode) {
32 return head;
33 }
34
35 // Skip 'n' nodes starting from previousNode.next for deletion
36 let currentNode: ListNode | null = previousNode;
37 for (let i = 0; i < n && currentNode != null; i++) {
38 currentNode = currentNode.next;
39 }
40
41 // Connect previousNode to the node after the 'n' nodes to delete
42 // If currentNode is not null, link to the node after the deleted sequence
43 // If currentNode is null, set the next of previousNode to null (end of list)
44 previousNode.next = currentNode ? currentNode.next : null;
45
46 // Move previousNode forward to start a new sequence
47 previousNode = previousNode.next;
48 }
49
50 // Return the head of the modified list
51 return head;
52}
53
Time and Space Complexity
Time Complexity
The time complexity of the given code involves iterating through each node of the linked list using two nested loops controlled by m
and n
. The outer while loop goes through each node, but the iteration is controlled by the logic that deletes every n
following m
nodes. Each node is visited at most once due to the nature of the single pass through the linked list. The for loop running m
times and the for loop running n
times are sequential and do not multiply their number of operations since they operate on different sets of nodes. Therefore, the time complexity of this function is O(m + n)
, for each group of m+n
nodes, with a total of O(T/m+n * (m + n))
= O(T)
where T
is the total number of nodes in the linked list.
Space Complexity
As there are no additional data structures that grow with the input size, and the given code only uses a fixed number of variables to keep track of the current and previous nodes, the space complexity is constant. Therefore, the space complexity is O(1)
.
Learn more about how to find time and space complexity quickly using problem constraints.
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