# Hash Table: Why deletion is difficult in open addressing scheme

I am trying to understand open Addressing method, I am refering TMH Corman Books in this topic it was stated that in open addressing Deletion is difficult, I am not able to understand this completely, the paragraph in which i Compltely stuck is Deletion from an open-address hash table is difficult. When we delete a key from slot i, we cannot simply mark that slot as empty by storing NIL in it. Doing so might make it impossible to retrieve any key k during whose insertion we had probed slot i and found it occupied Here I am not able to understand it, I am very thankful to you for your help. I have wested so much time on still i strugling with this, Please give explain me with some example.

Thanks

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Assume `hash(x) = hash(y) = hash(z) = i`. And assume `x` was inserted first, then `y` and then `z`.
In open addressing: `table[i] = x`, `table[i+1] = y`, `table[i+2] = z`.

Now, assume you want to delete `x`, and set it back to `NULL`.

When later you will search for `z`, you will find that `hash(z) = i` and `table[i] = NULL`, and you will return a wrong answer: `z` is not in the table.

To overcome this, you need to set `table[i]` with a special marker indicating to the search function to keep looking at index `i+1`, because there might be element there which its hash is also `i`.

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Amit: Thanks very much for your nice explanation – Nishant Feb 3 '12 at 11:00
@Nishant: You are welcome. glad it helped you. – amit Feb 3 '12 at 11:03
Amit: Can you please explain this: Three techniques are commonly used to compute the probe sequences required for open addressing: linear probing, quadratic probing, and double hashing. These techniques all guarantee that h(k, 1), h(k, 2), ., h(k, m) is a permutation of 0, 1, . . . , m - 1 for each key k. None of these techniques fulfills the assumption of uniform hashing, however, since none of them is capable of generating more than m2 different probe sequences (instead of the m! that uniform hashing requires). – Nishant Feb 3 '12 at 11:41
@Amit if you assuming that hash(x) = hash(y) = hash(z) = i , then how can it be represented by open addressing . In that case you you require to maintain a linked list(or some other kind of chaining) of the records right ? – Geek Aug 17 '12 at 12:53
@amit Also I have a related question here . can you try to answer that ? – Geek Aug 17 '12 at 12:55

In an open addressing scheme, lookups invoke a series of probes until either the key is found or and empty slot is found.

If one key involves a chain of several probes, it will be lost (not findable) if somewhere along the chain, one of the other keys is removed, leaving an empty slot where a stepping stone was needed.

The usual solution is to delete a key by marking its slot as available-for-resuse-but-not-actually empty. In other words, a replacement stepping stone is added so that probe chains to other keys aren't cut short.

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Deletion from a linear probed open addressed hash table is simple. There was pseudo code for it on the Wikipedia Hash Table page for years. I don't know why is isn't there any more, but here is a permalink back to when it was: Old Wikipedia Hash Table page, and here for your convenience is the pseudocode:

``````function remove(key)
i := find_slot(key)
if slot[i] is unoccupied
return   // key is not in the table
j := i
loop
j := (j+1) modulo num_slots
if slot[j] is unoccupied
exit loop
k := hash(slot[j].key) modulo num_slots
if (j > i and (k <= i or k > j)) or
(j < i and (k <= i and k > j)) (note 2)
slot[i] := slot[j]
i := j
mark slot[i] as unoccupied
``````

There is also a ref on that page to some real code. I believe this has exactly the same performance characteristic as insertion.

This method of deletion is better than the much used 'mark deleted and occasionally rehash everything' because the above method is constant time rather than amortized constant time. If you have a hash table of a million items you are adding and deleting from, in the 'mark deleted' method, an occasional add or delete is going to take a million times longer than the ones before and after it - which is not a good performance characteristic.

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