The brute force approach is to use recursion. First, we reach the end of the Linked List recursively and at last node, we return the last node, which becomes the new head of the partially r...read more

• Iterate through all nodes of the Linked list and push it to stack.
• Then update the head pointer to the top node of the stack.
• Then start popping each node from the stack and then assign the p...read more

We can improve our time complexity of finding the last node of partial reverse Linked List by the current node of each recursion call. If we look closer than the current node next is ac...read more

• Initially, we will take three-pointers, current that points to the head of Linked List, prev, and nextNode points to null.
• Then we will iterate over the linked list until the curr...read more

This approach is similar to the previous approach. While we are iterating the linked list we were swapping pointers using the third pointer, but in this approach, we will swap the pointers using only two pointers(one itself the given head) by using the property of XOR:

The property of XOR is:

• X⊕X = 0
• X⊕0 = X
• X⊕Y = Y⊕X
• (X⊕Y)⊕Z = X⊕(Y⊕Z)

Steps

• Initially, we will take two-pointers, given head that points to the head of Linked List, prev, points to null.
• Then we will iterate over the linked list until the current is not equal to NULL and do the following update in every step of the iteration:
  • prev = prev ⊕ head->next
  • head->next = prev ⊕ head->next
  • prev = prev ⊕ head->next
  • prev = prev ⊕ head
  • head= prev ⊕ head
  • prev = prev ⊕ head
• Now return the prev pointer which is now the head of reverse Linked List.

O(1)

In the worst case, only a constant extra space is required.

O(N), where N is the number of nodes in the linked list.

In the worst-case, we are iterating the whole linked list O(N). Hence, the overall complexity will be O(N).