Note: The course notes on objects, arrays, and references will be useful.

Quick Introduction to ArrayList

ArrayList Demo Project: arraylist-demo.zip

A common concern in Java programs is keeping track of collections of objects. Container classes, also known as collections, assist with this task: they allow your program to store collections of objects and then retrieve references to those objects when they are needed.

ArrayList (in the java.util package) is one of the simplest and most useful container classes. An ArrayList object works much like an array, but unlike an array, it has no fixed size, and expands as needed to store however many objects the program requires.

For example, let’s say that you’re writing a program to keep track of your friends’ email addresses. You could represent the email addresses as strings, and use an ArrayList to store them:

ArrayList<String> emailList = new ArrayList<String>();

Note that when declaring an ArrayList variable or creating a new ArrayList object, you must specify what type of objects the array list with contain. This type is called the element type.

To add strings to the list, call the add method:

emailList.add("jane_smith@yahoo.com");
emailList.add("sally.jones@gmail.com");
emailList.add("ben456@evilhacker.com");

Each object added to the list is appended onto the end of the sequence of objects.

The size method returns an integer value specifying the number of objects currently in the list. The get method allows you to retrieve the object at a specified index, where 0 is the first object in the sequence, 1 is the second object, etc:

// print all email addresses
for (int i = 0; i < emailList.size(); i++) {
String email = emailList.get(i);
System.out.println(email);
}

The set method takes an integer index and a reference to an object, and replaces the object at that index with the specified object. For example, if Jane Smith changes her email address, we could update our list as follows:

String oldEmail = "jane_smith@yahoo.com";
String newEmail = "jane_smith@us.ibm.com";
for (int i = 0; i < emailList.size(); i++) {
String email = emailList.get(i);
if (email.equals(oldEmail)) {
emailList.set(i, newEmail);
}
}

Note that we used the equals method to check whether an email address string was the same as Jane’s previous email address. We will discuss the equals method in Lecture 9.

Removing objects from a collection

Sometimes, you might need to remove some number of objects from a collection. The easiest and safest way to accomplish this task is to use a temporary collection object to store the objects you want to remove, and then use the removeAll method to remove them from the main collection.

For example, you might be concerned that email coming from the “evilhacker.com” site contains viruses. You could purge all addresses from this site from your email list as follows:

ArrayList<String> toRemove = new ArrayList<String>();

for (int i = 0; i < emailList.size(); i++) {
String email = emailList.get(i);
if (email.endsWith("@evilhacker.com")) {
// mark this address for removal
toRemove.add(email);
}
}

emailList.removeAll(toRemove);

Inheritance of fields and methods

When a superclass defines a field or non-private method, it is inherited by all subclasses.

So,

Access modifiers

We can specify access modifiers on fields and methods to restrict how they may be accessed. Java supports four access modifiers:

Even though Java supports four access modifiers, most of the time you will only use public and private.

Some rules of thumb:

One interesting consequence of these rules is that subclasses will not be allowed to directly access instance fields defined in the superclass. This is actually a good thing: it allows you to freely modify the fields in the superclass without affecting the subclasses in any way. (This is why protected fields are a bad idea - they make subclasses too sensitive to changes in the superclass.)

Defining Concrete Fields and Methods in a Superclass

Sometimes it can be useful to define concrete (non-abstract) fields and methods in superclasses.

You should do this only when the field and/or methods represent properties that are truly common to all subclasses.

Example:

public abstract class Vehicle {
private double maxSpeed;

public Vehicle(double maxSpeed) {
this.speed = maxSpeed;
}

public double getMaxSpeed() {
return maxSpeed;
}

public abstract boolean startTrip(Terrain t);
public abstract boolean endTrip(Terrain t);
public abstract boolean move(Terrain t);
}

Now all classes that inherit from the Vehicle superclass will have a double field called maxSpeed, and an instance method called getMaxSpeed which returns the value of that field.

Note that the Vehicle class is still abstract because it has abstract methods.

Invoking a superclass constructor from a subclass

When a superclass has instance fields, these fields exist in all instances of subclasses. So, constructors for subclasses will need a way to initialize these fields.

However, because instance fields are typically private, subclasses cannot access them directly. For example, here is a Car class that does not compile:

public class Car extends Vehicle {
public Car(double maxSpeed) {
// this doesn't work because the
// the maxSpeed field is private
// in the Vehicle class
this.maxSpeed = maxSpeed;
}

// ...definitions of startTrip, endTrip, and move methods...
}

The solution to this problem is for the Car class’s constructor to call the Vehicle class’s constructor. This is done using the super keyword. The call to the superclass’s constructor must be the first line of code in the subclass’s constructor:

public class Car extends Vehicle {
public Car(double maxSpeed) {
// call superclass (Vehicle) constructor
super(maxSpeed);
}

// ...definitions of startTrip, endTrip, and move methods...
}