1. Lists and the Collections Framework
Chapter 2
Lists and the Collections Framework

2. Chapter Objectives The List interface Linked list data structures:
Singly-linked
Doubly-linked
Circular
Big-O notation and algorithm efficiency
The Iterator interface
Implementing Iterator for a linked list
Testing strategies
The Java Collections framework (hierarchy)

3. Introduction
A list is a collection of elements, each with a position or index
Recursive definition of a list?
Iterators facilitate sequential access to lists
Classes ArrayList, Vector, and LinkedList are subclasses of abstract class AbstractList and implement the List interface

4. Static vs. Dynamic Structures
A static data structure has a fixed size
This meaning is different than those associated with the static modifier
Arrays are static; once you define the number of elements it can hold, it doesn’t change
A dynamic data structure grows and shrinks as required by the information it contains

5. List Interface and ArrayList Class (cont.)
Java provides a List interface as part of its API java.util
Classes that implement the List interface provide the functionality of an indexed data structure and offer many more operations
A sample of the operations:
Obtain an element at a specified position
Replace an element at a specified position
Find a specified target value
Add an element at either end
Remove an element from either end
Insert or removan element at any position
Traverse the list structure without managing a subscript
All classes introduced in this chapter support these operations, but they do not support them with the same degree of efficiency

6. Preliminaries Options for implementing an ADT List Array Linked list
Has a fixed size
Data must be shifted during insertions and deletions
Linked list
Is able to grow in size as needed
Does not require the shifting of items during insertions and deletions

7. Object References
Recall that an object reference is a variable that stores the address of an object
A reference can also be called a pointer
They are often depicted graphically:
student
John Smith
40725
3.57

8. Object References Figure 4.3a-d
a) Declaring reference variables; b) allocating an object; c) allocating another object, with the dereferenced object marked for garbage collection

9. References as Links
Object references can be used to create links between objects
Suppose a Student class contained a reference to another Student object
John Smith
40725
3.57
Jane Jones
58821
3.72

10. References as Links
References can be used to create a variety of linked structures, such as a linked list:
studentList

11. Preliminaries
Figure 4.1
a) A linked list of integers; b) insertion; c) deletion

12. Object References An array of objects
Is actually an array of references to the objects
Example
Integer[] scores = new Integer[30];
Instantiating Integer objects for each array reference
scores[0] = new Integer(7);
scores[1] = new Integer(9); // and so on …

13. Resizable Arrays
The number of references in a Java array is of fixed size
Resizable array
An array that grows and shrinks as the program executes
An illusion that is created by using an allocate and copy strategy with fixed-size arrays
java.util.Vector class
Uses a similar technique to implement a growable array of objects

14. Reference-Based Linked Lists
Contains nodes that are linked to one another
A node
Contains both data and a “link” to the next item
Can be implemented as an object
public class Node {
private Object item;
private Node next;
// constructors, accessors,
// and mutators …
} // end class Node
Figure 4.5
A node

15. Reference-Based Linked Lists
Using the Node class
Node n = new Node (new Integer(6));
Node first = new Node (new Integer(9), n);
Figure 4.7
Using the Node constructor to initialize a data field and a link value

16. Reference-Based Linked Lists
Data field next in the last node is set to null
head reference variable
References the list’s first node
Always exists even when the list is empty
Figure 4.8
A head reference to a linked list

17. Reference-Based Linked Lists
head reference variable can be assigned null without first using new
Following sequence results in a lost node
head = new Node(); // Don’t really need to use new here
head = null; // since we lose the new Node object here
Figure 4.9
A lost node

18. Programming with Linked Lists: Displaying the Contents of a Linked List
curr reference variable
References the current node
Initially references the first node
To display the data portion of the current node
System.out.println(curr.getItem());
To advance the current position to the next node
curr = curr.getNext();

19. Displaying the Contents of a Linked List
Figure 4.10
The effect of the assignment curr = curr.getNext( )

20. Displaying the Contents of a Linked List
To display all the data items in a linked list
for (Node curr = head; curr != null; curr = curr.getNext()) {
System.out.println(curr.getItem());
} // end for

21. Deleting a Specified Node from a Linked List
To delete node N which curr references
Set next in the node that precedes N to reference the node that follows N
prev.setNext(curr.getNext());
Figure 4.11
Deleting a node from a linked list

22. Deleting a Specified Node from a Linked List
Deleting the first node is a special case
head = head.getNext();
Figure 4.12
Deleting the first node

23. Inserting a Node into a Specified Position of a Linked List
To create a node for the new item
newNode = new Node(item);
To insert a node between two nodes
newNode.setNext(curr);
prev.setNext(newNode);
Figure 4.13
Inserting a new node into a linked list

24. Inserting a Node into a Specified Position of a Linked List
To insert a node at the beginning of a linked list
newNode.setNext(head);
head = newNode;
Figure 4.14
Inserting at the beginning of a linked list

25. Inserting a Node into a Specified Position of a Linked List
Inserting at the end of a linked list is not a special case if curr is null
newNode.setNext(curr);
prev.setNext(newNode);
Figure 4.15
Inserting at the end of a linked list

26. Inserting a Node into a Specified Position of a Linked List
Three steps to insert a new node into a linked list
Determine the point of insertion
Create a new node and store the new data in it
Connect the new node to the linked list by changing references

27. Determining curr and prev
Determining the point of insertion or deletion for a sorted linked list of objects
for ( prev = null, curr = head;
(curr != null) &&
(newValue.compareTo(curr.getItem()) > 0);
prev = curr, curr = curr.getNext() ) {
} // end for

28. A Reference-Based Implementation of the ADT List
Does not shift items during insertions and deletions
Does not impose a fixed maximum length on the list
Figure 4.18
A reference-based implementation of the ADT list

29. Comparing Array-Based and Referenced-Based Implementations
Size
Array-based
Fixed size
Issues
Can you predict the maximum number of items in the ADT?
Will an array waste storage?
Resizable array
Increasing the size of a resizable array can waste storage and time

30. Comparing Array-Based and Referenced-Based Implementations
Size (Continued)
Reference-based
Do not have a fixed size
Do not need to predict the maximum size of the list
Will not waste storage
Storage requirements
Array-based
Requires less memory than a reference-based implementation
There is no need to store explicitly information about where to find the next data item

31. Comparing Array-Based and Referenced-Based Implementations
Storage requirements (Continued)
Reference-based
Requires more storage
An item explicitly references the next item in the list
Access time
Array-based
Constant access time
The time to access the ith node depends on i

32. Comparing Array-Based and Referenced-Based Implementations
Insertion and deletions
Array-based
Require you to shift the data
Reference-based
Do not require you to shift the data
Require a list traversal

33. Passing a Linked List to a Method
A method with access to a linked list’s head reference has access to the entire list
When head is an actual argument to a method, its value is copied into the corresponding formal parameter
Figure 4.19
A head reference as an argument

34. Processing Linked List Recursively
Traversal
Recursive strategy to display a list
Write the first node of the list
Write the list minus its first node
Recursive strategies to display a list backward
writeListBackward strategy
Write the last node of the list
Write the list minus its last node backward
writeListBackward2 strategy
Write the list minus its first node backward

35. Processing Linked List Recursively
Insertion
Recursive view of a sorted linked list
The linked list that head references is a sorted linked list if
head is null (the empty list is a sorted linked list) or
head.getNext() is null (a list with a single node is a
sorted linked list)
head.getItem() < head.getNext().getItem(),
and head.getNext() references a sorted linked list

36. Variations of the Linked List: Tail References
Remembers where the end of the linked list is
To add a node to the end of a linked list
tail.setNext(new Node(request, null));
Figure 4.22
A linked list with head and tail references

37. Circular Linked List Last node references the first node
Every node has a successor
Figure 4.23
A circular linked list

38. Circular Linked List Figure 4.24
A circular linked list with an external reference to the last node

39. Doubly Linked List
Each node references both its predecessor and its successor
Figure 4.27
A doubly linked list

40. Doubly Linked List Circular doubly linked list
precede reference of the head node references the last node
next reference of the last node references the head node
Eliminates special cases for insertions and deletions

41. Doubly Linked List To delete the node that curr references
curr.getPrecede().setNext(curr.getNext());
curr.getNext().setPrecede(curr.getPrecede());
Figure 4.29
Reference changes for deletion

42. Doubly Linked List
To insert a new node that newNode references before the node referenced by curr
newNode.setNext(curr);
newNode.setPrecede(curr.getPrecede());
curr.setPrecede(newNode);
newNode.getPrecede().setNext(newNode);
Figure 4.30
Reference changes for insertion

43. Summary
Reference variables can be used to implement the data structure known as a linked list
Each reference in a linked list is a reference to the next node in the list
Algorithms for insertions and deletions in a linked list involve
Traversing the list from the beginning until you reach the appropriate position
Performing reference changes to alter the structure of the list

44. Summary
Inserting a new node at the beginning of a linked list and deleting the first node of a linked list are special cases
An array-based implementation uses an implicit ordering scheme; a reference-based implementation uses an explicit ordering scheme
Any element in an array can be accessed directly; you must traverse a linked list to access a particular node
Items can be inserted into and deleted from a reference-based linked list without shifting data

45. Summary
The new operator can be used to allocate memory dynamically for both an array and a linked list
The size of a linked list can be increased one node at a time more efficiently than that of an array
A binary search of a linked list is impractical
Recursion can be used to perform operations on a linked list
The recursive insertion algorithm for a sorted linked list works because each smaller linked list is also sorted

46. Summary
A tail reference can be used to facilitate locating the end of a list
In a circular linked list, the last node references the first node
Dummy head nodes eliminate the special cases for insertion into and deletion from the beginning of a linked list
A head record contains global information about a linked list
A doubly linked list allows you to traverse the list in either direction

47. java.util.List Interface and its Implementers

48. Algorithm Efficiency and Big-O
Section 2.4

49. Algorithm Efficiency and Big-O
Getting a precise measure of the performance of an algorithm is difficult
Big-O notation expresses the performance of an algorithm as a function of the number of items to be processed
This permits algorithms to be compared for efficiency
For more than a certain number of data items, some problems cannot be solved by any computer

50. Which is faster – selection sort or insertion sort?
Potential method for evaluation:
Implement each as a method and then Time each method to
see which is faster
Drawbacks
Implementation dependant, platform dependant, data dependant

51. What are the most important criteria that influence our algorithm implementation choices?
What do each of these criteria directly affect?

52. Experimental Studies Write a program implementing the algorithm
Run the program with inputs of varying size and composition
Use a method like System.currentTimeMillis() to get an accurate measure of the actual running time
Plot the results

53. Limitations of Experiments
It is necessary to implement the algorithm, which may be difficult
Results may not be indicative of the running time on other inputs not included in the experiment.
In order to compare two algorithms, the same hardware and software environments must be used

54. Theoretical Analysis
Uses a high-level description of the algorithm instead of an implementation
Characterizes running time as a function of the input size, n.
Takes into account all possible inputs
Allows us to evaluate the speed of an algorithm independent of the hardware/software environment

55. Asymptotic Analysis Big-O
The goal of asymptotic analysis is to determine the complexity order of an algorithm
Big-O
Two important rules:
Make g(n) as small as possible
g(n) never contains unnecessary terms

56. Big-Oh Rules
If is f(n) a polynomial of degree d, then f(n) is O(nd), i.e.,
Drop lower-order terms
Drop constant factors
Use the smallest possible class of functions
Say “2n is O(n)” instead of “2n is O(n2)”
Use the simplest expression of the class
Say “3n + 5 is O(n)” instead of “3n + 5 is O(3n)”

58. Figure 9.6
An insertion sort partitions the array into two regions

59. Figure 9.7
An insertion sort of an array of five integers.

61. Figure 9.4
A selection sort of an array of five integers

62. Order of Complexity Exponential Polynomial Log Linear Constant

63. Figure 9.3a
A comparison of growth-rate functions: a) in tabular form

64. Figure 9.3b
A comparison of growth-rate functions: b) in graphical form

67. Worst case: largest value for any problem of size n
Best case: smallest value for any problem of size n
Average case: (weighted) average of all problems of size n

68. Figure 9.5
The first two passes of a bubble sort of an array of five integers: a) pass 1;
b) pass 2

69. Figure 9.11
Levels of recursive calls to mergesort given an array of eight items

70. Figure 9.12
A partition about a pivot

71. Figure 9.22
Approximate growth rates of time required for eight sorting algorithms

72. Testing
Section 2.11

73. Testing
Testing runs a program or part of a program under controlled conditions to verify that results are as expected
Testing detects program defects after the program compiles (all syntax error have been removed)
While extremely useful, testing cannot detect the absence of all defects in complex programs

74. Testing Levels
Unit testing: tests the smallest testable piece of the software, often a class or a sufficiently complex method
Integration testing: tests integration among units
System testing: tests the whole program in the context in which it will be used
Acceptance testing: system testing designed to show that a program meets its functional requirements

75. Types of Testing Black-box testing:
tests the item (method, class, or program) based on its interfaces and functional requirements
is also called closed-box or functional testing
is accomplished by varying input parameters across the allowed range and outside the allowed range, and comparing with independently calculated results

76. Types of Testing (cont.)
White-box testing:
tests the item (method, class, or program) with knowledge of its internal structure
is also called glass-box, open-box, or coverage testing
exercises as many paths through the element as possible
provides appropriate coverage
statement – ensures each statement is executed at least once
branch – ensures each choice of branch (if , switch, loops) is taken
path – tests each path through a method

77. Preparations for Testing
A test plan should be developed early in the design stage—the earlier an error is detected, the easier and less expensive it is to correct it
Aspects of test plans include deciding:
how the software will be tested
when the tests will occur
who will do the testing
what test data will be used

78. Testing Tips for Program Systems
Carefully document method operation, parameter, and class attributes using comments; follow Javadoc conventions
Leave a trace of execution by displaying the method name as you enter it
Display values of all input parameters upon entering a method and values of any class attributes accessed by the method
Display values of all method outputs after returning from a method, together with any class attributes that are modified by a method

79. Testing Tips for Program Systems (cont.)
An efficient way to display values of parameters, return values, and class attributes:
private static final boolean TESTING = true; // or false to // disable
if (TESTING) {
// Code for output statements }
Remove these features when you are satisfied with tye testing results
You can define different boolean flags for different tests

80. Developing the Test Data
In black-box testing, test data should check for all expected inputs as well as unanticipated data
In white-box testing, test data should be designed to ensure all combinations of paths through the code are executed

81. Testing Boundary Conditions
Example
for (int i = 0; i < x.length; i++) {
if (x[i] == target)
return i; }
Test the boundary conditions (for white-box and black- box testing) when target is:
first element (x[0] == target is true)
last element (x[length-1] == target is true)
not in array (x[i] == target is always false)
present multiple times (x[i] == target for more than one value of i)

82. Testing Boundary Conditions (cont.)
for (int i = 0; i < x.length; i++) {
if (x[i] == target)
return i; }
Test for the typical situation when target is:
somewhere in the middle
and for the boundary conditions when the array has
only one element
no elements

83. Testing Boundary Conditions (cont.)
public static void main(String[] args) { int[] x = {5, 12, 15, 4, 8, 12, 7}; // Array to search. // Test for target as first element. verify(x, 5, 0); // Test for target as last element. verify(x, 7, 6); // Test for target not in array. verify(x, -5, -1); // Test for multiple occurrences of target. verify(x, 12, 1); // Test for target somewhere in middle. verify(x, 4, 3); // Test for 1-element array. x = new int[1]; x[0] = 10; verify(x, 10, 0); verify(x, -10, -1); // Test for an empty array. x = new int[0]; verify(x, 10, -1); }

84. Testing Boundary Conditions (cont.)
private static void verify(int[] x, int target, int expected) { int actual = search(x, target); System.out.print("search(x, " + target + ") is " + actual + ", expected " + expected); if (actual == expected) System.out.println(": Pass"); else System.out.println(": ****Fail"); }

85. Testing Boundary Conditions (cont.)

86. Stubs
Stubs are method placeholders for methods called by other classes, but not yet implemented
Stubs allowing testing as classes are being developed
A sample stub:
public void save() {
System.out.println("Stub for save has been called");
modified = false; }

87. Stubs (cont.) Stubs can print out value of inputs
assign predictable values to outputs
change the state of variables

88. Preconditions and Postconditions
A precondition is a statement of any assumptions or constraints on the input parameters before a method begins execution
A postcondition describes the result of executing the method, including any change to the object’s state
A method's preconditions and postconditions serve as a contract between a method caller and the method programmer
/** Method Save
pre: the initial directory contents are read from a data file
post: writes the directory contents back to a data file */
public void save() {
. . . }

89. Drivers Another testing tool A driver program
declares any necessary object instances and variables
assigns values to any of the method's inputs (specified by the preconditions)
calls the method
displays the outputs returned by the method
Driver program code can be added to a class's main method (each class can have a main method; only one main method - the one you designate to execute - will run)

90. Finally
JUnit, a popular program for Java projects, helps you develop testing programs (see Appendix C)
Many IDEs are shipped with debugger programs you can use for testing

91. Testing OrderedList To test an OrderedList,
store a collection of randomly generated integers in an OrderedList
test insertion at beginning of list: insert a negative integer
test insertion at end of list: insert an integer larger than any integer in the list
create an iterator and iterate through the list, displaying an error if any element is larger than the previous element
remove the first element, the last element, and a middle element, then traverse to show that order is maintained

92. Testing OrderedList (cont.)
Class TestOrderedList
import java.util.*;
public class TestOrderedList {
/** Traverses ordered list and displays each element.
Displays an error message if an element is out of order.
@param testList An ordered list of integers */
public static void traverseAndShow(OrderedList<Integer> testList) {
int prevItem = testList.get(0);
// Traverse ordered list and display any value that
// is out of order.
for (int thisItem : testList) {
System.out.println(thisItem);
if (prevItem > thisItem)
System.out.println("*** FAILED, value is "
+ thisItem);
prevItem = thisItem; }
public static void main(String[] args) {
OrderedList<Integer> testList = new OrderedList<Integer>();
final int MAX_INT = 500;
final int START_SIZE = 100;
(Con’t on next slide)

93. Testing OrderedList (cont.)
// Create a random number generator. Random random = new Random(); for (int i = 0; i < START_SIZE; i++) { int anInteger = random.nextInt(MAX_INT); testList.add(anInteger); } // Add to beginning and end of list. testList.add(-1); testList.add(MAX_INT + 1); traverseAndShow(testList); // Traverse and display. // Remove first, last, and middle elements. Integer first = testList.get(0); Integer last = testList.get(testList.size() - 1); Integer middle = testList.get(testList.size() / 2); testList.remove(first); testList.remove(last); testList.remove(middle);