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Hashing as a Dictionary Implementation Chapter 19.

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Presentation on theme: "Hashing as a Dictionary Implementation Chapter 19."— Presentation transcript:

1 Hashing as a Dictionary Implementation Chapter 19

2 2 Chapter Contents What is Hashing? Hash Functions Computing Hash Codes Compression a Hash Code into an Index for the Hash Table Resolving Collisions Open Addressing with Linear Probing Open Addressing with Quadratic Probing Open Addressing with Double Hashing A Potential Problem with Open Addressing Separate Chaining

3 3 Chapter Contents (ctd.) Efficiency The Load Factor The Cost of Open Addressing The Cost of Separate Chaining Rehashing Comparing Schemes for Collision Resolution A Dictionary Implementation that Uses Hashing Entries in the Hash Table Data Fields and Constructors The Methods getValue, remove, and addIterators Java Class Library: the Class HashMap

4 4 What is Hashing? A technique that determines an index or location for storage of an item in a data structure The hash function receives the search key Returns the index of an element in an array called the hash table The index is known as the hash index A perfect hash function maps each search key into a different integer suitable as an index to the hash table

5 5 What is Hashing? Fig. 19-1 A hash function indexes its hash table.

6 6 What is Hashing? Two steps of the hash function Convert the search key into an integer called the hash code Compress the hash code into the range of indices for the hash table Typical hash functions are not perfect They can allow more than one search key to map into a single index This is known as a collision

7 7 What is Hashing? Fig. 19-2 A collision caused by the hash function h

8 8 Hash Functions General characteristics of a good hash function Minimize collisions Distribute entries uniformly throughout the hash table Be fast to compute

9 9 Computing Hash Codes We will override the hashCode method of Object Guidelines If a class overrides the method equals, it should override hashCode If the method equals considers two objects equal, hashCode must return the same value for both objects If an object invokes hashCode more than once during execution of program on the same data, it must return the same hash code If an object's hash code during one execution of a program can differ from its hash code during another execution of the same program

10 10 Computing Hash Codes The hash code for a string, s Hash code for a primitive type Use the primitive typed key itself Manipulate internal binary representations Use folding int hash = 0; int n = s.length(); for (int i = 0; i < n; i++) hash = g * hash + s.charAt(i); // g is a positive constant

11 11 Compressing a Hash Code Must compress the hash code so it fits into the index range Typical method for a code c is to compute c modulo n n is a prime number (the size of the table) Index will then be between 0 and n – 1 private int getHashIndex(Object key) {int hashIndex = key.hashCode() % hashTable.length; if (hashIndex < 0) hashIndex = hashIndex + hashTable.length; return hashIndex; } // end getHashIndex

12 12 Resolving Collisions Options when hash functions returns location already used in the table Use another location in the table Change the structure of the hash table so that each array location can represent multiple values

13 13 Open Addressing with Linear Probing Open addressing scheme locates alternate location New location must be open, available Linear probing If collision occurs at hashTable[k], look successively at location k + 1, k + 2, …

14 14 Open Addressing with Linear Probing Fig. 19-3 The effect of linear probing after adding four entries whose search keys hash to the same index.

15 15 Open Addressing with Linear Probing Fig. 19-4 A revision of the hash table shown in 19-3 when linear probing resolves collisions; each entry contains a search key and its associated value

16 16 Removals Fig. 19-5 A hash table if remove used null to remove entries.

17 17 Removals We need to distinguish among three kinds of locations in the hash table 1.Occupied The location references an entry in the dictionary 2.Empty The location contains null and always did 3.Available The location's entry was removed from the dictionary

18 18 Open Addressing with Linear Probing Fig. 19-6 A linear probe sequence (a) after adding an entry; (b) after removing two entries;

19 19 Open Addressing with Linear Probing Fig. 19-6 A linear probe sequence (c) after a search; (d) during the search while adding an entry; (e) after an addition to a formerly occupied location.

20 20 Searches that Dictionary Operations Require To retrieve an entry Search the probe sequence for the key Examine entries that are present, ignore locations in available state Stop search when key is found or null reached To remove an entry Search the probe sequence same as for retrieval If key is found, mark location as available To add an entry Search probe sequence same as for retrieval Note first available slot Use available slot if the key is not found

21 21 Open Addressing, Quadratic Probing Change the probe sequence Given search key k Probe to k + 1, k + 2 2, k + 3 2, … k + n 2 Reaches every location in the hash table if table size is a prime number For avoiding primary clustering But can lead to secondary clustering

22 22 Open Addressing, Quadratic Probing Fig. 19-7 A probe sequence of length 5 using quadratic probing.

23 23 Open Addressing with Double Hashing Resolves collision by examining locations At original hash index Plus an increment determined by 2 nd function Second hash function Different from first Depends on search key Returns nonzero value Reaches every location in hash table if table size is prime Avoids both primary and secondary clustering

24 24 Open Addressing with Double Hashing Fig. 19-8 The first three locations in a probe sequence generated by double hashing for the search key.

25 25 Separate Chaining Alter the structure of the hash table Each location can represent multiple values Each location called a bucket Bucket can be a(n) List Sorted list Chain of linked nodes Array Vector

26 26 Separate Chaining Fig. 19-9 A hash table for use with separate chaining; each bucket is a chain of linked nodes.

27 27 Separate Chaining Fig. 19-10 Where new entry is inserted into linked bucket when integer search keys are (a) duplicate and unsorted;

28 28 Separate Chaining Fig. 19-10 Where new entry is inserted into linked bucket when integer search keys are (b) distinct and unsorted;

29 29 Separate Chaining Fig. 19-10 Where new entry is inserted into linked bucket when integer search keys are (c) distinct and sorted

30 30 Efficiency Observations Successful retrieval or removal Same efficiency as successful search Unsuccessful retrieval or removal Same efficiency as unsuccessful search Successful addition Same efficiency as unsuccessful search Unsuccessful addition Same efficiency as successful search

31 31 Load Factor Perfect hash function not always possible or practical Thus, collisions likely to occur As hash table fills Collisions occur more often Measure for table fullness, the load factor

32 32 Cost of Open Addressing Fig. 19-11 The average number of comparisons required by a search of the hash table for given values of the load factor when using linear probing.

33 33 Cost of Open Addressing Fig. 19-12 The average number of comparisons required by a search of the hash table for given values of the load factor when using either quadratic probing or double hashing. Note: for quadratic probing or double hashing, should have < 0.5

34 34 Cost of Separate Chaining Fig. 19-13 Average number of comparisons required by search of hash table for given values of load factor when using separate chaining. Note: Reasonable efficiency requires only < 1

35 35 Rehashing When load factor becomes too large Expand the hash table Double present size, increase result to next prime number Use method add to place current entries into new hash table

36 36 Comparing Schemes for Collision Resolution Fig. 19-14 Average number of comparisons required by search of hash table versus for 4 techniques when search is (a) successful; (b) unsuccessful.

37 37 A Dictionary Implementation That Uses Hashing Fig. 19-15 A hash table and one of its entry objects

38 38 Beginning of private class TableEntry Made internal to dictionary class A Dictionary Implementation That Uses Hashing private class TableEntry implements java.io.Serializable {private Object entryKey; private Object entryValue; private boolean inTable; // true if entry is in hash table private TableEntry(Object key, Object value) {entryKey = key; entryValue = value; inTable = true; } // end constructor...

39 39 A Dictionary Implementation That Uses Hashing Fig. 19-16 A hash table containing dictionary entries, removed entries, and null values.

40 40 Java Class Library: The Class HashMap Assumes search-key objects belong to a class that overrides methods hashCode and equals Hash table is collection of buckets Constructors public HashMap() public HashMap (int initialSize) public HashMap (int initialSize, float maxLoadFactor) public HashMap (Map table )

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