As per java, instance method resolution is based on runtime types of the arguments.
But while resolving instance variable it uses different approach as shown below.
Output of program is ..
Child
Parent
ParentNonStatic
Here First output is based on runtime types of the argument but third output is not.
can any one explain about this ?
public class Child extends Parent {
public static String foo = "Child";
public String hoo = "ChildNonStatic";
private Child() {
super(1);
}
#Override
String please() {
return "Child";
}
public static void main(String[] args) {
Parent p = new Parent();
Child c = new Child();
//Resolving method
System.out.println(((Parent) c).please());
//Resolving Static Variable
System.out.println(((Parent) c).foo);
//Resolving Instance Variable
System.out.println(((Parent) c).hoo);
}
}
class Parent {
public static String foo = "Parent";
public String hoo = "ParentNonStatic";
public Parent(int a) {
}
public Parent() {
}
String please() {
return "Tree";
}
}
When you upcast an object, you don't actually change the content of the item you are referring to, just the way you treat it. So when you upcast c to parent and call please(), you invoke please() on a Parent, but the dynamic type is still a child, so what really gets invoked is the overridden version in child and "Child" is printed.
When you upcast c and refer to foo, you are not making a function call. The compiler can determine at compile time what you are referring to. In this case, the field foo of an object that has the type parent. Fields and static fields are not overridden. Instead, they are hidden. What you actually end up doing with this upcast is helping Java pick the hidden version (the one from Parent) rather than the one from child. Similarly, with hoo you get the version of the parent.
Here's some info from the JAva tutorial: http://java.sun.com/docs/books/tutorial/java/IandI/hidevariables.html
In Java you don't actually "cast". Java doesn't actually do anything when you ask for a cast except to check if the object can be cast to that type thus why casts can throw a "ClassCastException".
The compiler though understands casts and thus uses them to validate that method calls are appropriate.
With respect to static fields, the compiler in fact removes any instance variables and references the field via the class according whatever the return type is.
Parent p = new Parent();
Child c = new Child();
Parent pc = new Child();
System.out.println(c.foo); // will print Child
System.out.println(p.foo); // will print Parent
System.out.println(pc.foo); // will print Parent
System.out.println(((Child)pc).foo) // will print Child
Fields seem to work the same way.
I think in a nutshell that java does dynamic binding on methods and static binding on fields.
Fields aren't overridden in the same way methods are. By casting c to Parent, you're indicating that ".hoo" refers to the "hoo" field on Parent, not the one on Child. (To put it in a more technically correct way, field access isn't polymorphic.)
Related
I am studying overriding member functions in Java and thought about experimenting with overriding member variables.
So, I defined classes
public class A{
public int intVal = 1;
public void identifyClass()
{
System.out.println("I am class A");
}
}
public class B extends A
{
public int intVal = 2;
public void identifyClass()
{
System.out.println("I am class B");
}
}
public class mainClass
{
public static void main(String [] args)
{
A a = new A();
B b = new B();
A aRef;
aRef = a;
System.out.println(aRef.intVal);
aRef.identifyClass();
aRef = b;
System.out.println(aRef.intVal);
aRef.identifyClass();
}
}
The output is:
1
I am class A
1
I am class B
I am not able to understand why when aRef is set to b intVal is still of class A?
When you make a variable of the same name in a subclass, that's called hiding. The resulting subclass will now have both properties. You can access the one from the superclass with super.var or ((SuperClass)this).var. The variables don't even have to be of the same type; they are just two variables sharing a name, much like two overloaded methods.
Variables are not polymorphic in Java; they do not override one another.
There is no polymorphism for fields in Java.
Variables decision happens at a compile time so always Base Class variables (not child’s inherited variables) will be accessed.
So whenever upcasting happens always remember
1) Base Class variables will be accessed.
2) Sub Class methods(overridden methods if overriding happened else inherited methods as it is from parent) will be called.
Variables are resolved compile-time, methods run-time. The aRef is of type A, therefore aRef.Intvalue is compile-time resolved to 1.
OverRiding Concept in Java
Functions will override depends on object type and variables will accessed on reference type.
Override Function: In this case suppose a parent and child class both have same name of function with own definition. But which function will execute it depends on object type not on reference type on run time.
For e.g.:
Parent parent=new Child();
parent.behaviour();
Here parent is a reference of Parent class but holds an object of Child Class so that's why Child class function will be called in that case.
Child child=new Child();
child.behaviour();
Here child holds an object of Child Class, so the Child class function will be called.
Parent parent=new Parent();
parent.behaviour();
Here parent holds the object of Parent Class, so the Parent class function will be called.
Override Variable: Java supports overloaded variables. But actually these are two different variables with same name, one in the parent class and one in the child class. And both variables can be either of the same datatype or different.
When you trying to access the variable, it depends on the reference type object, not the object type.
For e.g.:
Parent parent=new Child();
System.out.println(parent.state);
The reference type is Parent so the Parent class variable is accessed, not the Child class variable.
Child child=new Child();
System.out.println(child.state);
Here the reference type is Child, so the Child class variable is accessed not the Parent class variable.
Parent parent=new Parent();
System.out.println(parent.state);
Here the reference type is Parent, so Parent class variable is accessed.
From JLS Java SE 7 Edition §15.11.1:
This lack of dynamic lookup for field accesses allows programs to be run efficiently with straightforward implementations. The power of late binding and overriding is available, but only when instance methods are used.
Answers from Oliver Charlesworth and Marko Topolnik are correct, I would like to elaborate a little bit more on the why part of the question:
In Java class members are accessed according the type of the reference and not the type of the actual object. For the same reason, if you had a someOtherMethodInB() in class B, you wouldn't be able to access it from aRef after aRef = b is run. Identifiers (ie class, variable, etc names) are resolved at compile time and thus the compiler relies on the reference type to do this.
Now in your example, when running System.out.println(aRef.intVal); it prints the value of intVal defined in A because this is the type of the reference you use to access it. The compiler sees that aRef is of type A and that's the intVal it will access. Don't forget that you have both fields in the instances of B. JLS also has an example similar to yours, "15.11.1-1. Static Binding for Field Access" if you want to take a look.
But why do methods behave differently? The answer is that for methods, Java uses late binding. That means that at compile time, it finds the most suitable method to search for during the runtime. The search involves the case of the method being overridden in some class.
I hope this can help:
public class B extends A {
// public int intVal = 2;
public B() {
super();
super.intVal = 2;
}
public void identifyClass() {
System.out.println("I am class B");
}
}
So overriding variable of base class is not possible, but base class variable value can be set (changed) from constructor of inherited class.
This is called variable hiding. When you assign aRef = b; , aRef has two intVal, 1 is named just intVal another is hidden under A.intVal (see debugger screenshot), Because your variable is of type class A , even when you print just intVal java intelligently picks up A.intVal.
Answer 1: One way of accessing child class's intVal is System.out.println((B)aRef.intVal);
Answer 2: Another way of doing it is Java Reflection because when you use reflection java cant intelligently pickup hidden A.intVal based on Class type, it has to pick up the variable name given as string -
import java.lang.reflect.Field;
class A{
public int intVal = 1;
public void identifyClass()
{
System.out.println("I am class A");
}
}
class B extends A
{
public int intVal = 2;
public void identifyClass()
{
System.out.println("I am class B");
}
}
public class Main
{
public static void main(String [] args) throws Exception
{
A a = new A();
B b = new B();
A aRef;
aRef = a;
System.out.println(aRef.intVal);
aRef.identifyClass();
aRef = b;
Field xField = aRef.getClass().getField("intVal");
System.out.println(xField.get(aRef));
aRef.identifyClass();
}
}
Output -
1
I am class A
2
I am class B
Well, I hope u got the answer. If not, you can try seeing in the debug mode. the subclass B has access to both the intVal. They are not polymorphic hence they are not overriden.
If you use B's reference you will get B's intVal. If you use A's reference , you will get A's intVal. It's that simple.
As per the Java specifications, the instance variables are not overridden from a super class by a sub class when it is extended.
Hence the variable in the sub class only can be seen as one sharing the same name.
Also when the constructor of A is called during the instance creation of B the variable (intVal) is initialized and hence the output.
It is because when you assign b to aRef, it is resolved, leading aRef to just be of class A. This means that aRef does not have access to any of class B's fields or methods. If you call for intVal instead by using b.intVal, you will get 2.
Java has a feather of encapsulation means it tightly binds the property and the behavior of an object. so only via a class reference we can call it's behavior to change it's property.
and in inheritance only method overrides so that it can affects only it's property.
As Many users have already pointed out, this is not polymorphism. Polymorphism only applies to methods(functions).
Now as to why the value of the intVal of class A is printed, this happens because as you can see the reference aRef is of type A.
I can see why you are confused by it. By the same procedure you have accessed the overridden methods for ex. the method identifyClass() but the not the variables which directly proves the first line that I have written .
Now in order to access the variable you can do ((Superclass)c).var
Note here that the Superclass can be many levels up for example
A<-B<-C. That is C extends B and B extends A. If you wanted the value of var of A then you could have done ((A)c).var .
EDIT: as one of the users have pointed out this 'trick' does not apply to static methods, because they are static.
This question already has answers here:
Superclass reference not able to call subclass method in Java
(2 answers)
Closed 6 years ago.
Consider, for example, the following code
class Main {
public static void main(String[] args) {
Parent obj = new Child();
obj.firstMethod(); // Prints >> from child Class (polymorphism, great!)
obj.secondMethod(); // why this call fails?
// the obj variable reference a Child object
// which has secondMethod!
}
static class Parent {
Parent() {}
void firstMethod () {
System.out.println("from Parent Class");
}
}
static class Child extends Parent {
Child() {}
#Override
void firstMethod () {
System.out.println("from child Class");
}
void secondMethod () {
//
}
}
}
So obj variable is just a reference of type Parent, and the actual object the reference is pointing to is of type Child. I can't understand why such access fails!
Because the declared type Parent doesn't contain the method : void secondMethod ().
So, the compilation fails.
The polymorphism works only if both classes (Parent and Child) have a common method which comes from the parent class and that the child class overrides as in your firstMethod() example.
In your case, you call a method specific to the child class, so you should declare
Child obj = new Child() or do a cast to Child when you call secondMethod().
Don't forget that Polymorphism allows variables to have a dynamic behavior by using at runtime the implementation of the effective instance behind the variable. It is therefore meaningful only if the classes share a same operation.
The language spec answer: refer to JLS Sec 15.12. Emphasis added.
15.12.1. Compile-Time Step 1: Determine Class or Interface to Search
The first step in processing a method invocation at compile time is to figure out the name of the method to be invoked and which class or interface to search for definitions of methods of that name.
...
For the class or interface to search, there are six cases to consider, depending on the form that precedes the left parenthesis of the MethodInvocation:
...
If the form is ExpressionName . [TypeArguments] Identifier, then the class or interface to search is the declared type T of the variable denoted by ExpressionName if T is a class or interface type, or the upper bound of T if T is a type variable.
15.12.2. Compile-Time Step 2: Determine Method Signature
The second step searches the type determined in the previous step for member methods.
In obj.secondMethod();, ExpressionName is obj, which has declared type Parent. As such, the declared type T is Parent, not Child, so only methods in Parent are searched for. There's no method in Parent called secondMethod, so it's a compile-time error.
I am studying overriding member functions in Java and thought about experimenting with overriding member variables.
So, I defined classes
public class A{
public int intVal = 1;
public void identifyClass()
{
System.out.println("I am class A");
}
}
public class B extends A
{
public int intVal = 2;
public void identifyClass()
{
System.out.println("I am class B");
}
}
public class mainClass
{
public static void main(String [] args)
{
A a = new A();
B b = new B();
A aRef;
aRef = a;
System.out.println(aRef.intVal);
aRef.identifyClass();
aRef = b;
System.out.println(aRef.intVal);
aRef.identifyClass();
}
}
The output is:
1
I am class A
1
I am class B
I am not able to understand why when aRef is set to b intVal is still of class A?
When you make a variable of the same name in a subclass, that's called hiding. The resulting subclass will now have both properties. You can access the one from the superclass with super.var or ((SuperClass)this).var. The variables don't even have to be of the same type; they are just two variables sharing a name, much like two overloaded methods.
Variables are not polymorphic in Java; they do not override one another.
There is no polymorphism for fields in Java.
Variables decision happens at a compile time so always Base Class variables (not child’s inherited variables) will be accessed.
So whenever upcasting happens always remember
1) Base Class variables will be accessed.
2) Sub Class methods(overridden methods if overriding happened else inherited methods as it is from parent) will be called.
Variables are resolved compile-time, methods run-time. The aRef is of type A, therefore aRef.Intvalue is compile-time resolved to 1.
OverRiding Concept in Java
Functions will override depends on object type and variables will accessed on reference type.
Override Function: In this case suppose a parent and child class both have same name of function with own definition. But which function will execute it depends on object type not on reference type on run time.
For e.g.:
Parent parent=new Child();
parent.behaviour();
Here parent is a reference of Parent class but holds an object of Child Class so that's why Child class function will be called in that case.
Child child=new Child();
child.behaviour();
Here child holds an object of Child Class, so the Child class function will be called.
Parent parent=new Parent();
parent.behaviour();
Here parent holds the object of Parent Class, so the Parent class function will be called.
Override Variable: Java supports overloaded variables. But actually these are two different variables with same name, one in the parent class and one in the child class. And both variables can be either of the same datatype or different.
When you trying to access the variable, it depends on the reference type object, not the object type.
For e.g.:
Parent parent=new Child();
System.out.println(parent.state);
The reference type is Parent so the Parent class variable is accessed, not the Child class variable.
Child child=new Child();
System.out.println(child.state);
Here the reference type is Child, so the Child class variable is accessed not the Parent class variable.
Parent parent=new Parent();
System.out.println(parent.state);
Here the reference type is Parent, so Parent class variable is accessed.
From JLS Java SE 7 Edition §15.11.1:
This lack of dynamic lookup for field accesses allows programs to be run efficiently with straightforward implementations. The power of late binding and overriding is available, but only when instance methods are used.
Answers from Oliver Charlesworth and Marko Topolnik are correct, I would like to elaborate a little bit more on the why part of the question:
In Java class members are accessed according the type of the reference and not the type of the actual object. For the same reason, if you had a someOtherMethodInB() in class B, you wouldn't be able to access it from aRef after aRef = b is run. Identifiers (ie class, variable, etc names) are resolved at compile time and thus the compiler relies on the reference type to do this.
Now in your example, when running System.out.println(aRef.intVal); it prints the value of intVal defined in A because this is the type of the reference you use to access it. The compiler sees that aRef is of type A and that's the intVal it will access. Don't forget that you have both fields in the instances of B. JLS also has an example similar to yours, "15.11.1-1. Static Binding for Field Access" if you want to take a look.
But why do methods behave differently? The answer is that for methods, Java uses late binding. That means that at compile time, it finds the most suitable method to search for during the runtime. The search involves the case of the method being overridden in some class.
I hope this can help:
public class B extends A {
// public int intVal = 2;
public B() {
super();
super.intVal = 2;
}
public void identifyClass() {
System.out.println("I am class B");
}
}
So overriding variable of base class is not possible, but base class variable value can be set (changed) from constructor of inherited class.
This is called variable hiding. When you assign aRef = b; , aRef has two intVal, 1 is named just intVal another is hidden under A.intVal (see debugger screenshot), Because your variable is of type class A , even when you print just intVal java intelligently picks up A.intVal.
Answer 1: One way of accessing child class's intVal is System.out.println((B)aRef.intVal);
Answer 2: Another way of doing it is Java Reflection because when you use reflection java cant intelligently pickup hidden A.intVal based on Class type, it has to pick up the variable name given as string -
import java.lang.reflect.Field;
class A{
public int intVal = 1;
public void identifyClass()
{
System.out.println("I am class A");
}
}
class B extends A
{
public int intVal = 2;
public void identifyClass()
{
System.out.println("I am class B");
}
}
public class Main
{
public static void main(String [] args) throws Exception
{
A a = new A();
B b = new B();
A aRef;
aRef = a;
System.out.println(aRef.intVal);
aRef.identifyClass();
aRef = b;
Field xField = aRef.getClass().getField("intVal");
System.out.println(xField.get(aRef));
aRef.identifyClass();
}
}
Output -
1
I am class A
2
I am class B
Well, I hope u got the answer. If not, you can try seeing in the debug mode. the subclass B has access to both the intVal. They are not polymorphic hence they are not overriden.
If you use B's reference you will get B's intVal. If you use A's reference , you will get A's intVal. It's that simple.
As per the Java specifications, the instance variables are not overridden from a super class by a sub class when it is extended.
Hence the variable in the sub class only can be seen as one sharing the same name.
Also when the constructor of A is called during the instance creation of B the variable (intVal) is initialized and hence the output.
It is because when you assign b to aRef, it is resolved, leading aRef to just be of class A. This means that aRef does not have access to any of class B's fields or methods. If you call for intVal instead by using b.intVal, you will get 2.
Java has a feather of encapsulation means it tightly binds the property and the behavior of an object. so only via a class reference we can call it's behavior to change it's property.
and in inheritance only method overrides so that it can affects only it's property.
As Many users have already pointed out, this is not polymorphism. Polymorphism only applies to methods(functions).
Now as to why the value of the intVal of class A is printed, this happens because as you can see the reference aRef is of type A.
I can see why you are confused by it. By the same procedure you have accessed the overridden methods for ex. the method identifyClass() but the not the variables which directly proves the first line that I have written .
Now in order to access the variable you can do ((Superclass)c).var
Note here that the Superclass can be many levels up for example
A<-B<-C. That is C extends B and B extends A. If you wanted the value of var of A then you could have done ((A)c).var .
EDIT: as one of the users have pointed out this 'trick' does not apply to static methods, because they are static.
I am studying overriding member functions in Java and thought about experimenting with overriding member variables.
So, I defined classes
public class A{
public int intVal = 1;
public void identifyClass()
{
System.out.println("I am class A");
}
}
public class B extends A
{
public int intVal = 2;
public void identifyClass()
{
System.out.println("I am class B");
}
}
public class mainClass
{
public static void main(String [] args)
{
A a = new A();
B b = new B();
A aRef;
aRef = a;
System.out.println(aRef.intVal);
aRef.identifyClass();
aRef = b;
System.out.println(aRef.intVal);
aRef.identifyClass();
}
}
The output is:
1
I am class A
1
I am class B
I am not able to understand why when aRef is set to b intVal is still of class A?
When you make a variable of the same name in a subclass, that's called hiding. The resulting subclass will now have both properties. You can access the one from the superclass with super.var or ((SuperClass)this).var. The variables don't even have to be of the same type; they are just two variables sharing a name, much like two overloaded methods.
Variables are not polymorphic in Java; they do not override one another.
There is no polymorphism for fields in Java.
Variables decision happens at a compile time so always Base Class variables (not child’s inherited variables) will be accessed.
So whenever upcasting happens always remember
1) Base Class variables will be accessed.
2) Sub Class methods(overridden methods if overriding happened else inherited methods as it is from parent) will be called.
Variables are resolved compile-time, methods run-time. The aRef is of type A, therefore aRef.Intvalue is compile-time resolved to 1.
OverRiding Concept in Java
Functions will override depends on object type and variables will accessed on reference type.
Override Function: In this case suppose a parent and child class both have same name of function with own definition. But which function will execute it depends on object type not on reference type on run time.
For e.g.:
Parent parent=new Child();
parent.behaviour();
Here parent is a reference of Parent class but holds an object of Child Class so that's why Child class function will be called in that case.
Child child=new Child();
child.behaviour();
Here child holds an object of Child Class, so the Child class function will be called.
Parent parent=new Parent();
parent.behaviour();
Here parent holds the object of Parent Class, so the Parent class function will be called.
Override Variable: Java supports overloaded variables. But actually these are two different variables with same name, one in the parent class and one in the child class. And both variables can be either of the same datatype or different.
When you trying to access the variable, it depends on the reference type object, not the object type.
For e.g.:
Parent parent=new Child();
System.out.println(parent.state);
The reference type is Parent so the Parent class variable is accessed, not the Child class variable.
Child child=new Child();
System.out.println(child.state);
Here the reference type is Child, so the Child class variable is accessed not the Parent class variable.
Parent parent=new Parent();
System.out.println(parent.state);
Here the reference type is Parent, so Parent class variable is accessed.
From JLS Java SE 7 Edition §15.11.1:
This lack of dynamic lookup for field accesses allows programs to be run efficiently with straightforward implementations. The power of late binding and overriding is available, but only when instance methods are used.
Answers from Oliver Charlesworth and Marko Topolnik are correct, I would like to elaborate a little bit more on the why part of the question:
In Java class members are accessed according the type of the reference and not the type of the actual object. For the same reason, if you had a someOtherMethodInB() in class B, you wouldn't be able to access it from aRef after aRef = b is run. Identifiers (ie class, variable, etc names) are resolved at compile time and thus the compiler relies on the reference type to do this.
Now in your example, when running System.out.println(aRef.intVal); it prints the value of intVal defined in A because this is the type of the reference you use to access it. The compiler sees that aRef is of type A and that's the intVal it will access. Don't forget that you have both fields in the instances of B. JLS also has an example similar to yours, "15.11.1-1. Static Binding for Field Access" if you want to take a look.
But why do methods behave differently? The answer is that for methods, Java uses late binding. That means that at compile time, it finds the most suitable method to search for during the runtime. The search involves the case of the method being overridden in some class.
I hope this can help:
public class B extends A {
// public int intVal = 2;
public B() {
super();
super.intVal = 2;
}
public void identifyClass() {
System.out.println("I am class B");
}
}
So overriding variable of base class is not possible, but base class variable value can be set (changed) from constructor of inherited class.
This is called variable hiding. When you assign aRef = b; , aRef has two intVal, 1 is named just intVal another is hidden under A.intVal (see debugger screenshot), Because your variable is of type class A , even when you print just intVal java intelligently picks up A.intVal.
Answer 1: One way of accessing child class's intVal is System.out.println((B)aRef.intVal);
Answer 2: Another way of doing it is Java Reflection because when you use reflection java cant intelligently pickup hidden A.intVal based on Class type, it has to pick up the variable name given as string -
import java.lang.reflect.Field;
class A{
public int intVal = 1;
public void identifyClass()
{
System.out.println("I am class A");
}
}
class B extends A
{
public int intVal = 2;
public void identifyClass()
{
System.out.println("I am class B");
}
}
public class Main
{
public static void main(String [] args) throws Exception
{
A a = new A();
B b = new B();
A aRef;
aRef = a;
System.out.println(aRef.intVal);
aRef.identifyClass();
aRef = b;
Field xField = aRef.getClass().getField("intVal");
System.out.println(xField.get(aRef));
aRef.identifyClass();
}
}
Output -
1
I am class A
2
I am class B
Well, I hope u got the answer. If not, you can try seeing in the debug mode. the subclass B has access to both the intVal. They are not polymorphic hence they are not overriden.
If you use B's reference you will get B's intVal. If you use A's reference , you will get A's intVal. It's that simple.
As per the Java specifications, the instance variables are not overridden from a super class by a sub class when it is extended.
Hence the variable in the sub class only can be seen as one sharing the same name.
Also when the constructor of A is called during the instance creation of B the variable (intVal) is initialized and hence the output.
It is because when you assign b to aRef, it is resolved, leading aRef to just be of class A. This means that aRef does not have access to any of class B's fields or methods. If you call for intVal instead by using b.intVal, you will get 2.
Java has a feather of encapsulation means it tightly binds the property and the behavior of an object. so only via a class reference we can call it's behavior to change it's property.
and in inheritance only method overrides so that it can affects only it's property.
As Many users have already pointed out, this is not polymorphism. Polymorphism only applies to methods(functions).
Now as to why the value of the intVal of class A is printed, this happens because as you can see the reference aRef is of type A.
I can see why you are confused by it. By the same procedure you have accessed the overridden methods for ex. the method identifyClass() but the not the variables which directly proves the first line that I have written .
Now in order to access the variable you can do ((Superclass)c).var
Note here that the Superclass can be many levels up for example
A<-B<-C. That is C extends B and B extends A. If you wanted the value of var of A then you could have done ((A)c).var .
EDIT: as one of the users have pointed out this 'trick' does not apply to static methods, because they are static.
I tried to upcast an objet. But at runtime object class is remained as a derived class.
Derived drv = new Derived();
Base base = (Base) drv;
System.out.println("Class : " + base.getClass());
//prints -> Class : class packagename.Derived
So Why class property didn't change?
So Why class property didn't change?
Because the object hasn't changed, just the type of the reference you have to it. Casting has no effect at all on the object itself.
In Java, unlike some other languages (thankfully), the type of the reference largely doesn't affect which version of a method you get. For instance, consider these two classes (courtesy of 2rs2ts — thank you!):
class Base {
public Base() {}
public void foo() {
System.out.println("I'm the base!");
}
}
class Child extends Base {
public Child() {}
public void foo() {
System.out.println("I'm the child!");
}
}
This code:
Child x = new Child();
Base y = (Base) x;
y.foo();
...outputs
I'm the child!
because even though the type of y is Base, the object that we're calling foo on is a Child, and so Child#foo gets called. Here (again courtesy of 2rs2ts) is an example on ideone to play with.
The fact that we get Child#foo despite going through a Base reference is crucial to polymorphism.
Now, it just so happens that the method you were calling (getClass) can only be Object#getClass, because it's a final method (subclasses cannot override it). But the concept is crucial and I figured it was probably the core of what you were asking about.
The chief thing that the type of the reference does is determine what aspects of an object you're allowed to access. For instance, suppose we add bar to Child:
class Child extends Base {
public Child() {}
public void foo() {
System.out.println("I'm the child!");
}
public void bar() {
System.out.println("I'm Child#bar");
}
}
This code won't compile:
Child x = new Child();
Base y = (Base) x;
y.bar(); // <=== Compilation error
...because Base has no bar method, and so we can't access the object's bar method through a reference with type Base.
You can not change the type of an instance in Java. All you're doing with your cast is reference it from a variable of a different type.
An upcast does not change the object's type. As a matter of fact, NOTHING changes a Java object's type.
That's the very core of OO programming: An object has a defined behavior that can't be influenced from the outside.