# Hashing | Set 3 (Open Addressing)

We strongly recommend to refer below post as a prerequisite of this.

Hashing | Set 1 (Introduction)

Hashing | Set 2 (Separate Chaining)

**Open Addressing**

Like separate chaining, open addressing is a method for handling collisions. In Open Addressing, all elements are stored in the hash table itself. So at any point, size of the table must be greater than or equal to the total number of keys (Note that we can increase table size by copying old data if needed).

Insert(k): Keep probing until an empty slot is found. Once an empty slot is found, insert k.

Search(k): Keep probing until slot’s key doesn’t become equal to k or an empty slot is reached.

Delete(k): * Delete operation is interesting*. If we simply delete a key, then search may fail. So slots of deleted keys are marked specially as “deleted”.

Insert can insert an item in a deleted slot, but the search doesn’t stop at a deleted slot.

Open Addressing is done following ways:

* a) Linear Probing:* In linear probing, we linearly probe for next slot. For example, typical gap between two probes is 1 as taken in below example also.

let

**hash(x)**be the slot index computed using hash function and

**S**be the table size

If slot hash(x) % S is full, then we try (hash(x) + 1) % S If (hash(x) + 1) % S is also full, then we try (hash(x) + 2) % S If (hash(x) + 2) % S is also full, then we try (hash(x) + 3) % S .................................................. ..................................................

Let us consider a simple hash function as “key mod 7” and sequence of keys as 50, 700, 76, 85, 92, 73, 101.

**Clustering:** The main problem with linear probing is clustering, many consecutive elements form groups and it starts taking time to find a free slot or to search an element.

* b) Quadratic Probing* We look for i

^{2}‘th slot in i’th iteration.

let hash(x) be the slot index computed using hash function. If slot hash(x) % S is full, then we try (hash(x) + 1*1) % S If (hash(x) + 1*1) % S is also full, then we try (hash(x) + 2*2) % S If (hash(x) + 2*2) % S is also full, then we try (hash(x) + 3*3) % S .................................................. ..................................................

**c) Double Hashing** We use another hash function hash2(x) and look for i*hash2(x) slot in i’th rotation.

let hash(x) be the slot index computed using hash function. If slot hash(x) % S is full, then we try (hash(x) + 1*hash2(x)) % S If (hash(x) + 1*hash2(x)) % S is also full, then we try (hash(x) + 2*hash2(x)) % S If (hash(x) + 2*hash2(x)) % S is also full, then we try (hash(x) + 3*hash2(x)) % S .................................................. ..................................................

See this for step by step diagrams.

**Comparison of above three:**

Linear probing has the best cache performance but suffers from clustering. One more advantage of Linear probing is easy to compute.

Quadratic probing lies between the two in terms of cache performance and clustering.

Double hashing has poor cache performance but no clustering. Double hashing requires more computation time as two hash functions need to be computed.

S.No. | Separate Chaining |
Open Addressing |

1. | Chaining is Simpler to implement. | Open Addressing requires more computation. |

2. | In chaining, Hash table never fills up, we can always add more elements to chain. | In open addressing, table may become full. |

3. | Chaining is Less sensitive to the hash function or load factors. | Open addressing requires extra care for to avoid clustering and load factor. |

4. | Chaining is mostly used when it is unknown how many and how frequently keys may be inserted or deleted. | Open addressing is used when the frequency and number of keys is known. |

5. | Cache performance of chaining is not good as keys are stored using linked list. | Open addressing provides better cache performance as everything is stored in the same table. |

6. | Wastage of Space (Some Parts of hash table in chaining are never used). | In Open addressing, a slot can be used even if an input doesn’t map to it. |

7. | Chaining uses extra space for links. | No links in Open addressing |

**Performance of Open Addressing:**

Like Chaining, the performance of hashing can be evaluated under the assumption that each key is equally likely to be hashed to any slot of the table (simple uniform hashing)

m = Number of slots in the hash table n = Number of keys to be inserted in the hash table Load factor α = n/m ( < 1 ) Expected time to search/insert/delete < 1/(1 - α) So Search, Insert and Delete take (1/(1 - α)) time

References:

http://courses.csail.mit.edu/6.006/fall11/lectures/lecture10.pdf

https://www.cse.cuhk.edu.hk/irwin.king/_media/teaching/csc2100b/tu6.pdf

Please write comments if you find anything incorrect, or you want to share more information about the topic discussed above.

Don’t stop now and take your learning to the next level. Learn all the important concepts of Data Structures and Algorithms with the help of the most trusted course: **DSA Self Paced**. Become industry ready at a student-friendly price.

## Recommended Posts:

- Convert an array to reduced form | Set 1 (Simple and Hashing)
- Cuckoo Hashing - Worst case O(1) Lookup!
- Top 20 Hashing Technique based Interview Questions
- Hashing | Set 1 (Introduction)
- Hashing | Set 2 (Separate Chaining)
- Union and Intersection of two linked lists | Set-3 (Hashing)
- Implementing own Hash Table with Open Addressing Linear Probing in C++
- Index Mapping (or Trivial Hashing) with negatives allowed
- Practice Problems on Hashing
- C++ program for hashing with chaining
- Double Hashing
- Coalesced hashing
- Majority Element | Set-2 (Hashing)
- Applications of Hashing
- Hashing in Java
- Address Calculation Sort using Hashing
- Rearrange characters in a string such that no two adjacent are same using hashing
- Extendible Hashing (Dynamic approach to DBMS)
- Area of the largest square that can be formed from the given length sticks using Hashing
- Quadratic Probing in Hashing