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Why is the time complexity of node deletion in doubly linked lists (O(1)) faster than node deletion in singly linked lists (O(n))?

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Homework? Write the code for deleting a node from a singly linked list, and then it'll be obvious. – Jason Orendorff Dec 13 '09 at 6:53
I think there shouldn't be abbrevations like dll in the title, but i can't think of a better one. – Georg Fritzsche Dec 13 '09 at 7:08

The problem assumes that the node to be deleted is known and a pointer to that node is available.

In order to delete a node and connect the previous and the next node together, you need to know their pointers. In a doubly-linked list, both pointers are available in the node that is to be deleted. The time complexity is constant in this case, i.e., O(1).

Whereas in a singly-linked list, the pointer to the previous node is unknown and can be found only by traversing the list from head until it reaches the node that has a next node pointer to the node that is to be deleted. The time complexity in this case is O(n).

In cases where the node to be deleted is known only by value, the list has to be searched and the time complexity becomes O(n) in both singly- and doubly-linked lists.

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It has to do with the complexity of fixing up the next pointer in the node previous to the one you're deleting.

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Because you can't look backwards...

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Insertion and deletion at a known position is O(1). However, finding that position is O(n), unless it is the head or tail of the list.

When we talk about insertion and deletion complexity, we generally assume we already know where that's going to occur.

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