Chapter 11 - Sorting and Searching

Chapter 11 Sorting and Searching

Chapter 10 Objectives After you have read and studied this chapter, you should be able to Perform linear and binary search algorithms on small arrays. Determine whether a linear or binary search is more effective for a given situation. Perform selection and bubble sort algorithms. Describe the heapsort algorithm and show how its performance is superior to the other two algorithms. Apply basic sorting algorithms to sort an array of objects.

Searching When we maintain a collection of data, one of the operations we need is a search routine to locate desired data quickly. Here’s the problem statement: Given a value X, return the index of X in the array, if such X exists. Otherwise, return NOT_FOUND (-1). We assume there are no duplicate entries in the array. We will count the number of comparisons the algorithms make to analyze their performance. The ideal searching algorithm will make the least possible number of comparisons to locate the desired data. Two separate performance analyses are normally done, one for successful search and another for unsuccessful search.

Search Result number Unsuccessful Search: Successful Search: 23 17 5 90 12 44 38 0 1 2 3 4 5 6 7 8 84 77 NOT_FOUND search( 45 ) search( 12 ) 4

Linear Search Search the array from the first to the last position in linear progression. public int linearSearch ( int [] number, int searchValue ) { int loc = 0; while ( loc < number.length && number[loc] != searchValue ) { loc++; } if ( loc == number.length ) { //Not found return NOT_FOUND; } else { return loc; //Found, return the position } }

Linear Search Performance We analyze the successful and unsuccessful searches separately. We count how many times the search value is compared against the array elements. Successful Search Best Case – 1 comparison Worst Case – N comparisons (N – array size) Unsuccessful Search Best Case = Worst Case – N comparisons

Binary Search If the array is sorted, then we can apply the binary search technique. The basic idea is straightforward. First search the value in the middle position. If X is less than this value, then search the middle of the left half next. If X is greater than this value, then search the middle of the right half next. Continue in this manner. number 5 12 17 23 38 44 77 0 1 2 3 4 5 6 7 8 84 90

Sequence of Successful Search - 1 search( 44 ) low high mid 38 < 44 5 12 17 23 38 44 77 0 1 2 3 4 5 6 7 8 84 90 0 8 #1 high low low = mid+1 = 5 mid 4

Sequence of Successful Search - 2 search( 44 ) low high mid 44 < 77 4 5 12 17 23 38 44 77 0 1 2 3 4 5 6 7 8 84 90 0 8 #1 high = mid-1=5 mid 6 high low 5 8 #2

Sequence of Successful Search - 3 search( 44 ) low high mid 44 == 44 4 6 Successful Search!! 5 12 17 23 38 44 77 0 1 2 3 4 5 6 7 8 84 90 0 8 #1 5 8 #2 high low 5 5 #3 mid 5

Sequence of Unsuccessful Search - 1 search( 45 ) low high mid 38 < 45 5 12 17 23 38 44 77 0 1 2 3 4 5 6 7 8 84 90 0 8 #1 high low low = mid+1 = 5 mid 4

Sequence of Unsuccessful Search - 2 search( 45 ) low high mid 45 < 77 4 5 12 17 23 38 44 77 0 1 2 3 4 5 6 7 8 84 90 0 8 #1 high = mid-1=5 mid 6 high low 5 8 #2

Sequence of Unsuccessful Search - 3 search( 45 ) low high mid 44 < 45 4 6 5 12 17 23 38 44 77 0 1 2 3 4 5 6 7 8 84 90 0 8 #1 5 8 #2 high low 5 5 #3 mid 5 low = mid+1 = 6

Sequence of Unsuccessful Search - 4 search( 45 ) low high mid 4 6 5 Unsuccessful Search low > high 5 12 17 23 38 44 77 0 1 2 3 4 5 6 7 8 84 90 0 8 #1 5 8 #2 5 5 #3 high low 6 5 #4 no more elements to search

Binary Search Routine public int binarySearch ( int [] number, int searchValue ) { int low = 0, high = number.length - 1, mid = (low + high) / 2; while ( low <= high && number[mid] != searchValue ) { if ( number [ mid ] < searchValue ) { low = mid + 1; } else { //number[mid] > searchValue high = mid - 1; } mid = ( low + high ) / 2; //integer division will truncate } if ( low > high ) { mid = NOT_FOUND; } return mid; }

Binary Search Performance Successful Search Best Case – 1 comparison Worst Case – log 2 N comparisons Unsuccessful Search Best Case = Worst Case – log 2 N comparisons Since the portion of an array to search is cut into half after every comparison, we compute how many times the array can be divided into halves. After K comparisons, there will be N/2 K elements in the list. We solve for K when N/2 K = 1, deriving K = log 2 N.

Comparing N and log 2 N Performance Array Size Linear – N Binary – log 2 N

Sorting When we maintain a collection of data, many applications call for rearranging the data in certain order, e.g. arranging Person information in ascending order of age. Here’s the problem statement: Given an array of N integer values, arrange the values into ascending order. We will count the number of comparisons the algorithms make to analyze their performance. The ideal sorting algorithm will make the least possible number of comparisons to arrange data in a designated order. We will compare different sorting algorithms by analyzing their worst-case performance.

Selection Sort Find the smallest element in the list. Exchange the element in the first position and the smallest element. Now the smallest element is in the first position. Repeat Step 1 and 2 with the list having one less element (i.e., the smallest element is discarded from further processing). This is the result of one pass . 0 1 2 3 4 5 6 7 8 23 17 5 90 12 44 38 84 77 min first exchange 0 1 2 3 4 5 6 7 8 5 17 23 90 12 44 38 84 77 sorted unsorted

Selection Sort Passes 2 3 7 8 Result AFTER one pass is completed. 0 1 2 3 4 5 6 7 8 5 17 23 90 12 44 38 84 77 sorted 5 12 23 90 17 44 38 84 77 5 12 17 90 23 44 38 84 77 5 12 17 23 38 44 77 84 90 5 12 17 23 38 44 77 84 90 1 Pass #

Selection Sort Routine public void selectionSort ( int [] number ) { int startIndex, minIndex, length, temp; length = number.length; for ( startIndex = 0; startIndex <= length-2; startIndex++ ){ //each iteration of the for loop is one pass minIndex = startIndex; //find the smallest in this pass at position minIndex for ( int i = startIndex+1; i <= length-1; i++ ) { if (number [ i ] < number [ minIndex ]) minIndex = i; } //exchange number[startIndex] and number[minIndex] temp = number [ startIndex ] ; number [ startIndex ] = number [ minIndex ] ; number [ minIndex ] = temp; } }

Selection Sort Performance We derive the total number of comparisons by counting the number of times the inner loop is executed. For each execution of the outer loop, the inner loop is executed length – start times. The variable length is the size of the array. Replacing length with N, the array size, the sum is derived as…

Bubble Sort With the selection sort, we make one exchange at the end of one pass. The bubble sort improves the performance by making more than one exchange during its pass. By making multiple exchanges, we will be able to move more elements toward their correct positions using the same number of comparisons as the selection sort makes. The key idea of the bubble sort is to make pairwise comparisons and exchange the positions of the pair if they are out of order.

One Pass of Bubble Sort The largest value 90 is at the end of the list. ok 0 1 2 3 4 5 6 7 8 23 17 5 90 12 44 38 84 77 17 23 5 90 12 44 38 84 77 17 5 23 90 12 44 38 84 77 17 5 23 12 90 44 38 84 77 17 5 23 12 44 90 38 84 77 17 5 23 12 44 38 90 84 77 17 5 23 12 44 38 84 90 77 17 5 23 12 44 38 84 77 90 exchange exchange exchange exchange exchange exchange exchange

Bubble Sort Routine public void bubbleSort ( int [] number ) { int temp, bottom, i; boolean exchanged = true; bottom = number.length - 2; while ( exchanged ) { exchanged = false ; for ( i = 0; i <= bottom; i++ ) { if (number [ i ] > number [ i+1 ]) { temp = number [ i ] ; //exchange number [ i ] = number [ i+1 ] ; number [ i+1 ] = temp; exchanged = true ; //exchange is made } } bottom--; } }

Bubble Sort Performance In the worst case, the outer while loop is executed N-1 times for carrying out N-1 passes. For each execution of the outer loop, the inner loop is executed bottom+1 times. The number of comparisons in each successive pass is N-1, N-2, … , 1. Summing these will result in the total number of comparisons. So the performances of the bubble sort and the selection sort are approximately equivalent. However, on the average, the bubble sort performs much better than the selection sort because it can finish the sorting without doing all N-1 passes.

Heapsort Selection and bubble sorts are two fundamental sorting algorithms that take approximately N2 comparisons to sort an array of N elements. One sorting algorithm that improves the performance to approximately 1.5Nlog2N is called heapsort. The heapsort algorithm uses a special data structure called a heap. A heap structure can be implemented very effectively by using an array.

Sample Heap 90 84 44 12 5 38 77 17 23 0 1 2 3 4 5 6 7 8 root index left child of 44 right child of 44 Level # 1 2 3 4

Heap Constraints A heap must satisfy the following two constraints: Structural Constraint : Nodes in a heap with N nodes must occupy the positions numbered 0, 1, ..., N-1. Value Relationship Constraint : A value stored in a node must be larger than the maximum of the values stored in its left and right children.

Structural Constraints Sample heaps and nonheaps that violate the structural constraints: Nonheaps Heaps

Value Relationship Constraints Sample heaps and nonheaps that violate the value relationship constraints: Nonheaps Heaps 45 25 16 3 12 22 45 12 34 11 22 9 90 35 24 13 16 12 45 55 16 3 12 58 45 25 33 34 23 22 45 25 55 3 12 22

Heapsort Algorithm How can we use the heap structure to sort N elements? Heapsort is carried out in two phases: Construction Phase : Construct a heap with given N elements. Extraction Phase : Pull out the value in the root successively, creating a new heap with one less element after each extraction.

Extraction Phase After each extraction, a heap must be rebuilt with one less element. One sample extraction step: 90 23 > max{84, 44}? NO, so swap. 23 > max{77, 12}? NO, so swap. 23 > max{17}? YES, so stop. Before After 90 84 44 12 5 38 77 17 23 0 1 2 3 4 5 6 7 8 0 1 2 3 4 5 6 7 8 90 23 84 44 12 5 38 77 17 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 8 90 84 23 44 12 5 38 77 17 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 8 90 84 77 44 12 5 38 23 17 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 8 90 84 77 44 12 5 38 23 17 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 8 90 90 84 44 12 5 38 77 17 23 0 1 2 3 4 5 6 7 8 0 1 2 3 4 5 6 7 8

Rebuild Steps A sequence of rebuild steps to sort the list. 90 84 77 44 38 23 17 12 5 Sorting was completed after 8 rebuild steps. 90 84 44 12 5 38 77 17 23 0 1 2 3 4 5 6 7 8 0 1 2 3 4 5 6 7 8 90 84 44 12 5 38 77 17 23 0 1 2 3 4 5 6 7 8 0 1 2 3 4 5 6 7 8 Before 90 84 77 44 12 5 38 23 17 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 8 90 84 77 23 44 12 5 38 17 0 1 2 3 4 5 6 0 1 2 3 4 5 6 7 8 90 84 77 44 23 38 12 5 17 0 1 2 3 4 5 0 1 2 3 4 5 6 7 8 90 84 77 44 38 23 5 12 17 0 1 2 3 4 0 1 2 3 4 5 6 7 8 90 84 77 44 38 23 17 5 12 0 1 2 3 0 1 2 3 4 5 6 7 8 90 84 77 44 38 23 17 12 5 0 1 2 0 1 2 3 4 5 6 7 8 90 84 77 44 38 23 17 12 5 0 1 0 1 2 3 4 5 6 7 8 90 84 77 44 38 23 17 12 5 0 0 1 2 3 4 5 6 7 8 90 84 77 44 38 23 17 12 5 0 1 2 3 4 5 6 7 8 90 84 77 44 38 23 17 12 5 Done

Construction Phase Rebuild steps are applied from position  (N-2)/2  to position 0. Before 23 17 5 12 44 38 90 84 77 0 1 2 3 4 5 6 7 8 23 17 5 12 44 38 90 84 77 0 1 2 3 4 5 6 7 8 3  (9-2)/2  = 3 23 17 5 12 44 38 90 84 77 0 1 2 3 4 5 6 7 8 2 23 17 44 12 5 38 90 84 77 0 1 2 3 4 5 6 7 8 1 23 90 44 12 5 38 84 17 77 0 1 2 3 4 5 6 7 8 0 90 84 44 12 5 38 77 17 23 0 1 2 3 4 5 6 7 8 Done

Heap Implementation We need to implement the abstract data structure heap into a concrete data structure. 90 84 44 12 5 38 77 17 23 0 1 2 3 4 5 6 7 8 Abstract Heap Structure Concrete Implementation 0 1 2 3 4 5 6 7 8 23 17 38 5 12 77 44 84 90

The construct Method private void construct ( ) { for ( int i = ( heap.length-2 ) / 2; i >= 0; i-- ) { current = i; done = false ; while ( !done ) { if ( current has no children ) { done = true; } else { if ( current node < larger child ) { swap the two nodes ; set current points to the larger child ; } else { done = true ; } } } } }

The extract Method private void extract ( ) { for ( int size = heap.length-1; size >= 0; size-- ) { remove the root node data ; move the last node to the root; done = false ; //rebuild the heap with one less element while ( !done ) { if ( current has no children ) { done = true ; } else { if ( current node < larger child ) { swap the two nodes ; set current points to the larger child ; } else { done = true ; } } } } }

Heapsort Performance The total number of comparisons in the extraction phase is (N-1)  K where K is the depth of a heap. We solve for K using the fact that the heap must satisfy the structural constraint: Therefore, total # nodes in a heap with depth K this holds because of the structural constraint

Heapsort Performance (cont'd) There are N/2 rebuild steps in the construction phase. Each rebuild step will take no more than K comparisons. The total number of comparisons in the construction phase is approximately Therefore, the total number of comparisons for both phases is

Problem Statement Problem statement: Add the sorting capability to the AddressBook class from Chapter 10. The new AddressBook class will include a method that sort Person objects in alphabetical order of their names or in ascending order of their ages.

Overall Plan Instead of going through the development steps, we will present three different implementations. The three versions are named AddressBookVer1, AddressBookVer2, and AddressBookVer3. These classes will implement the AddressBook interface.

The AddressBook Interface interface AddressBook { public void add ( Person newPerson ) ; public boolean delete ( String searchName ) ; public Person search ( String searchName ) ; public Person [ ] sort ( int attribute ) ; }

AddressBookVer1 Design We use an array of Person objects We provide our own sorting method in the AddressBookVer1 class We define the Person class so we can compare Person objects by name or by age

Comparing Person Objects First, we need to determine how to compare Person objects The following does not make sense: Person p1 = …; Person p2 = …; if ( p1 < p2 ) { … }

Modify the Person Class Modify the Person class to include a variable that tells which attribute to compare. class Person { … public static final int NAME = 0; public static final int AGE = 1; public static int compareAttribute = NAME; … public static void setCompareAttribute ( int attribute ) { compareAttribute = attribute; } … }

The compareTo Method To compare Person objects, first set the comparison attribute and then call the compareTo Method. Person.setCompareAttribute (Person.NAME); int compResult = p1.compareTo ( p2 ) ; if ( compResult < 0 ) { //p1 “less than” p2 } else if ( compResult == 0 ) { //p1 “equals” pw } else { //p2 “greater than” p2 } public int compareTo ( Person p ) { int compResult; if ( comparisonAttribute == AGE ) { int p2age = p.getAge(); if ( this .age < p2age ) { compResult = LESS; } … } else { //compare Name String p2Name = p.getName () ; compResult = this .name. compareTo ( p2Name ) ; } return compResult; }

The sort Method public Person [ ] sort ( int attribute ) { Person [ ] sortedList = new Person [ count ] ; Person p1, p2, temp; //copy references to sortedList for ( int i = 0; i < count; i++ ) { sortedList [ i ] = entry [ i ] ; } //Set the comparison attribute Person.setCompareAttribute ( attribute ) ; //begin the bubble sort on sortedList … } return sortedList; }

The Use of sortedList in the sort Method

AddressBookVer1 Code Directory: Chapter11/ Source Files: AddressBookVer1.java Program source file is too big to list here. From now on, we ask you to view the source files using your Java IDE.

AddressBookVer2 Design We use the java.util.Arrays class to sort an array of Person objects The Person class does not include any comparison methods. Instead, we implement the Comparator interface. We can define the implementation class so we can compare Person objects using any combination of their attributes For example, we can define a comparator that compares Person objects by using both name and age

The AgeComparator Class This class compares the age attributes of Person objects class AgeComparator implements Comparator { private final int LESS = -1; private final int EQUAL = 0; private final int MORE = 1; public int compare ( Object p1, Object p2 ) { int comparisonResult; int p1age = (( Person ) p1 ) .getAge ( ) ; int p2age = (( Person ) p2 ) .getAge ( ) ; if ( p1age < p2age ) { comparisonResult = LESS; } else if ( p1age == p2age ) { comparisonResult = EQUAL; } else { assert p1age > p2age; comparisonResult = MORE; } return comparisonResult; } }

The NameComparator Class This class compares the age attributes of Person objects Because the name attribute is a string we can use the compareTo method of the String class class NameComparator implements Comparator { public int compare ( Object p1, Object p2 ) { String p1name = (( Person ) p1 ) .getName ( ) ; String p2name = (( Person ) p2 ) .getName ( ) ; return p1name.compareTo ( p2name ) ; } }

The sort Method We use the sort method of the java.util.Arrays class public Person [ ] sort ( int attribute ) { if ( ! ( attribute == Person.NAME || attribute == Person.AGE ) ) { throw new IllegalArgumentException ( ) ; } Person [ ] sortedList = new Person [ count ] ; //copy references to sortedList for ( int i = 0; i < count; i++ ) { sortedList [ i ] = entry [ i ] ; } Arrays.sort ( sortedList, getComparator ( attribute )) ; return sortedList; }

AddressBookVer3 Design In the previous two versions, we used an array data structure to maintain a collection of Person objects In the third version, we don't use an array at all. Instead, we use a Map from the Java Collection Framework to maintain a collection of Person objects. We use the person's name as the key of a Map entry and the person object as the value of a Map entry.

The sort Method We retrieve a collection of values in the map, converts it to an array, and use the sort method of the java.util.Arrays class to sort this array. public Person [ ] sort ( int attribute ) { if ( ! ( attribute == Person.NAME || attribute == Person.AGE ) ) { throw new IllegalArgumentException ( ) ; } Person [ ] sortedList = new Person [ entry.size ()] ; entry.values () .toArray ( sortedList ) ; Arrays.sort ( sortedList, getComparator ( attribute )) ; return sortedList; }

Chapter 11 - Sorting and Searching

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Chapter 11 - Sorting and Searching

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