Introduction to Algorithms (CLRS) states that a hash table using doubly linked lists is able to delete items more quickly than one with singly linked lists. Can anybody tell me what is the advantage of using doubly linked lists instead of single linked list for deletion in Hashtable implementation?

The confusion here is due to the notation in CLRS. To be consistent with the true question, I use the CLRS notation in this answer. We use the hash table to store keyvalue pairs. The value portion is not mentioned in the CLRS pseudocode, while the key portion is defined as In my copy of CLR (I am working off of the first edition here), the routines listed for hashes with chaining are insert, search, and delete (with more verbose names in the book). The insert and delete routines take argument Since Additional DiscussionAlthough CLRS says that you can do the deletion in O(1) time, assuming a doublylinked list, it also requires you have The pseudocode routines are lower level than you would use if presenting a hash table interface to a user. For instance, a delete routine that takes a key 


I can think of one reason, but this isn't a very good one. Suppose we have a hash table of size 100. Now suppose values A and G are each added to the table. Maybe A hashes to slot 75. Now suppose G also hashes to 75, and our collision resolution policy is to jump forward by a constant step size of 80. So we try to jump to (75 + 80) % 100 = 55. Now, instead of starting at the front of the list and traversing forward 85, we could start at the current node and traverse backwards 20, which is faster. When we get to the node that G is at, we can mark it as a tombstone to delete it. Still, I recommend using arrays when implementing hash tables. 


Hashtable is often implemented as a vector of lists. Where index in vector is the key (hash). 


Let's design the data structures for a caching proxy. We need a map from URLs to content; let's use a hash table. We also need a way to find pages to evict; let's use a FIFO queue to track the order in which URLs were last accessed, so that we can implement LRU eviction. In C, the data structure could look something like
One subtlety: to avoid a special case and wasting space in the hash buckets,
When evicting, we iterate over the least recently accessed nodes via the 


If the items in your hashtable are stored in "intrusive" lists, they can be aware of the linked list they are a member of. Thus, if the intrusive list is also doublylinked, items can be quickly removed from the table. (Note, though, that the "intrusiveness" can be seen as a violation of abstraction principles...) An example: in an objectoriented context, an intrusive list might require all items to be derived from a base class.
The performance advantage is that any item can be quickly removed from its doublylinked list without locating or traversing the rest of the list. 


Unfortunately my copy of CLRS is in another country right now, so I can't use it as a reference. However, here's what I think it is saying: Basically, a doubly linked list supports O(1) deletions because if you know the address of the item, you can just do something like:
to delete the object from the linked list, while as in a linked list, even if you have the address, you need to search through the linked list to find its predecessor to do:
So, when you delete an item from the hash table, you look it up, which is O(1) due to the properties of hash tables, then delete it in O(1), since you now have the address. If this was a singly linked list, you would need to find the predecessor of the object you wish to delete, which would take O(n). However: I am also slightly confused about this assertion in the case of chained hash tables, because of how lookup works. In a chained hash table, if there is a collision, you already need to walk through the linked list of values in order to find the item you want, and thus would need to also find its predecessor. But, the way the statement is phrased gives clarification: "If the hash table supports deletion, then its linked lists should be doubly linked so that we can delete an item quickly. If the lists were only singly linked, then to delete element x, we would first have to find x in the list T[h(x.key)] so that we could update the next attribute of x’s predecessor." This is saying that you already have element x, which means you can delete it in the above manner. If you were using a singly linked list, even if you had element x already, you would still have to find its predecessor in order to delete it. 

