I am confused by the behaviour of the static method when it is overridden in the subclass.
Below is the code:
public class SuperClass {
public static void staticMethod() {
System.out.println("SuperClass: inside staticMethod");
}
}
public class SubClass extends SuperClass {
//overriding the static method
public static void staticMethod() {
System.out.println("SubClass: inside staticMethod");
}
}
public class CheckClass {
public static void main(String[] args) {
SuperClass superClassWithSuperCons = new SuperClass();
SuperClass superClassWithSubCons = new SubClass();
SubClass subClassWithSubCons = new SubClass();
superClassWithSuperCons.staticMethod();
superClassWithSubCons.staticMethod();
subClassWithSubCons.staticMethod();
}
}
Below is the output which we are getting :
1) SuperClass: inside staticMethod
2) SuperClass: inside staticMethod
3) SubClass: inside staticMethod
Why static method of superclass gets called here in the second case?
If method is not static, then according to polymorphism, method of the subclass is called when subclass object is passed on runtime.
static method resolution is always based on the Reference type.
The code
superClassWithSuperCons.staticMethod();
superClassWithSubCons.staticMethod();
subClassWithSubCons.staticMethod();
is converted to this after compilation
SuperClass.staticMethod();
SuperClass.staticMethod();
SubClass.staticMethod();
Accroding to this it is the call to SuperClass method not the subclass method.So you are getting the output of SuperClass method.
A method declared static cannot be overridden but can be re-declared. That's the answer.
A static method is not associated with any instance of a class so the concept is not applicable. Try the same with not static and you'll see the difference.
Your question is duplicated actually:
Why doesn't Java allow overriding of static methods?
Interesting question. I'm not familiar with the underlying mechanisms, but it seems that for static methods, the declared type (in your middle example, SuperClass), not the actual type SubClass is considered for resolving the method call. It actually makes sense because you're not looking at the actual instance of an object when calling a static function.
Static methods are redefined not overridden...
If you try to override the static method then it will be treated as a non overridden method of the sub class.
Static methods will be called based on the type of the reference not the object created.
For more information visit the page.
http://javaunturnedtopics.blogspot.in/2016/07/static-methods-are-redefined-not.html
So I know that in Java when you have a static method you are supposed to call it with the format ClassName.method() rather than use the same structure as you would for instance methods, namely:
ClassName myObject = new ClassName();
myObject.method();
However, if you were to do it this way it would still be valid code and would work. Let's say I decide to do this where the method in question is static, and have the following setup:
public SuperClass {
public static int foo(int x) {
return x;
}
}
public SubClass extends SuperClass {
public static int foo(int x) { // Overriding foo() in SuperClass
return x + 1;
}
}
public MyDriver {
public static void main(String[] args) {
SuperClass myObject = new SubClass(); // Upcasting.
System.out.println(myObject.foo(5)); // This should polymorphically print 6
}
}
What prints out on the screen, however, is 5 rather than 6. Why?
Static methods apply only to the class they are defined in, and they cannot be overridden.
When you call myObject.foo(5), you are calling SuperClass.foo(5) in reality, because you declared myObject as a SuperClass, regardless of whether you instantiated it as one.
The proper way to call a static method is to call it directly from the class it is declared in, so if you wanted to call SubClass.foo(), you must call it from an explicitly declared SubClass instance (meaning no upcasting), or you need to call SubClass.foo() like so.
The simple answer is that calling static methods from instances evaluates to calling those same methods from the declared type with no instance rather than the instance type.
I am not certain of this, but I would not be surprised if when the code is compiled into byte-code, that the instance static method call would actually be compiled into a direct call to the declared type.
Edit: An upvote brought my attention back to this and I cleaned up the explanation to make it more clear and fix some negligible grammatical mistakes on my part. I hope this helps future readers.
Using instances of a class to call that class's static methods is something you should avoid, since it can cause confusion. If you need to call any method polymorphically, make it an instance method. You cannot polymorphically call a static method. The reason the SuperClass invocation is called is because that is the apparent class of myObject at compile-time. This effect can also be seen in the following scenario:
public void doSomething(SuperClass param) {
System.out.println("SuperClass");
}
public void doSomething(SubClass param) {
System.out.println("SubClass");
}
public void test() {
SuperClass myObject = new SubClass();
doSomething(myObject);
}
If test() is called, SuperClass will be printed.
Static methods don't depends on the instance, they belong to the class and only to the class, in fact if you have a static method you'll always access to one unique instance always.
myObject.foo(5)
is only a shortcut, what you really are doing is
SuperClass.foo(5)
Static methods are treated as global by the JVM, they are not bound to an object instance at all. By the way, you can only overload static methods, but you can not override. So check for "Oracle Documentation for Overriding and Hiding Documents".
Defining a Method with the Same Signature as a Superclass's Method:
-----------------------------------------Superclass Instance MethodSuperclass Static Method
Subclass Instance Method Overrides Generates a compile-time error
Subclass Static Method Generates a compile-time error Hides
I have the following code snippet that attempts to use this and super.
class SuperClass
{
public final int x=10;
public final String s="super";
public String notOverridden()
{
return "Inside super";
}
public String overrriden()
{
return "Inside super";
}
}
final class SubClass extends SuperClass
{
private final int y=15;
private final String s="sub"; //Shadowed member.
#Override
public String overrriden()
{
return "Inside sub";
}
public void test()
{
System.out.println(super.notOverridden());
System.out.println(this.notOverridden());
System.out.println(this.overrriden());
System.out.println(super.overrriden());
System.out.println(this.s);
System.out.println(super.s);
System.out.println(this.x);
System.out.println(super.x);
System.out.println(this.y);
}
}
public final class Test
{
public static void main(String[] args)
{
SubClass subClass=new SubClass();
subClass.test();
}
}
In this simplest of Java code, the statements that redirect the output to the console inside the method test() within the class SubClass display the following output.
Inside super
Inside super
Inside sub
Inside super
sub
super
10
10
15
So, it appears that there is no difference between this and super, when they are used to access methods which are not overridden in its subclass(es) and in case of variables, when they are not shadowed in its subclass(es).
Both of them tend to point to super class members. There is however, an obvious difference, if such is not a case.
Are they same, when methods are not overridden or variables are not shadowed in respective subclasses?
So, it appears that there is no difference between this and super,
when they are used to access methods which are not overridden in
its subclass(es) and in case of variables, when they are not
shadowed in its subclass(es).
There is a difference. If you override methods in third class, and call test from it, you will see, that super still calls implementations of SuperClass. And this will call new implementations (overridden).
Addition:
this.method() usage implies the method belongs to instance of the object. So the last implementation will be used (with exception of private methods).
super.method() usage implies method of the instance, but implemented before the current class (super, or super.super etc).
Yes, they are the same. notOverridden methods and not shadowed variables are inherited by subclass.
To better understand this, knowing how object is located in memory is helpful. For example in the figure below. Assume it's an object of a subclass. The blue area is what it inherits from its parent, and the yellow area is what is defined by itself. The method has the similar design except that it uses a Vtable.
Child object has the same memory layout as parent objects, except that it needs more space to place the newly added fields. The benefit of this layout is that a pointer of parent type pointing at a subclass object still sees the parent object at the beginning.
The question is in Java why can't I define an abstract static method? for example
abstract class foo {
abstract void bar( ); // <-- this is ok
abstract static void bar2(); //<-- this isn't why?
}
Because "abstract" means: "Implements no functionality", and "static" means: "There is functionality even if you don't have an object instance". And that's a logical contradiction.
Poor language design. It would be much more effective to call directly a static abstract method than creating an instance just for using that abstract method. Especially true when using an abstract class as a workaround for enum inability to extend, which is another poor design example. Hope they solve those limitations in a next release.
You can't override a static method, so making it abstract would be meaningless. Moreover, a static method in an abstract class would belong to that class, and not the overriding class, so couldn't be used anyway.
The abstract annotation to a method indicates that the method MUST be overriden in a subclass.
In Java, a static member (method or field) cannot be overridden by subclasses (this is not necessarily true in other object oriented languages, see SmallTalk.) A static member may be hidden, but that is fundamentally different than overridden.
Since static members cannot be overriden in a subclass, the abstract annotation cannot be applied to them.
As an aside - other languages do support static inheritance, just like instance inheritance. From a syntax perspective, those languages usually require the class name to be included in the statement. For example, in Java, assuming you are writing code in ClassA, these are equivalent statements (if methodA() is a static method, and there is no instance method with the same signature):
ClassA.methodA();
and
methodA();
In SmallTalk, the class name is not optional, so the syntax is (note that SmallTalk does not use the . to separate the "subject" and the "verb", but instead uses it as the statemend terminator):
ClassA methodA.
Because the class name is always required, the correct "version" of the method can always be determined by traversing the class hierarchy. For what it's worth, I do occasionally miss static inheritance, and was bitten by the lack of static inheritance in Java when I first started with it. Additionally, SmallTalk is duck-typed (and thus doesn't support program-by-contract.) Thus, it has no abstract modifier for class members.
I also asked the same question , here is why
Since Abstract class says, it will not give implementation and allow subclass to give it
so Subclass has to override the methods of Superclass ,
RULE NO 1 - A static method cannot be overridden
Because static members and methods are compile time elements , that is why Overloading(Compile time Polymorphism) of static methods are allowed rather then Overriding (Runtime Polymorphism)
So , they cant be Abstract .
There is no thing like abstract static <--- Not allowed in Java Universe
This is a terrible language design and really no reason as to why it can't be possible.
In fact, here is a pattern or way on how it can be mimicked in **Java ** to allow you at least be able to modify your own implementations:
public static abstract class Request {
// Static method
public static void doSomething() {
get().doSomethingImpl();
}
// Abstract method
abstract void doSomethingImpl();
/////////////////////////////////////////////
private static Request SINGLETON;
private static Request get() {
if ( SINGLETON == null ) {
// If set(request) is never called prior,
// it will use a default implementation.
return SINGLETON = new RequestImplementationDefault();
}
return SINGLETON;
}
public static Request set(Request instance){
return SINGLETON = instance;
}
/////////////////////////////////////////////
}
Two implementations:
/////////////////////////////////////////////////////
public static final class RequestImplementationDefault extends Request {
#Override void doSomethingImpl() {
System.out.println("I am doing something AAA");
}
}
/////////////////////////////////////////////////////
public static final class RequestImplementaionTest extends Request {
#Override void doSomethingImpl() {
System.out.println("I am doing something BBB");
}
}
/////////////////////////////////////////////////////
Could be used as follows:
Request.set(new RequestImplementationDefault());
// Or
Request.set(new RequestImplementationTest());
// Later in the application you might use
Request.doSomething();
This would allow you to invoke your methods statically, yet be able to alter the implementation say for a Test environment.
Theoretically, you could do this on a ThreadLocal as well, and be able to set instance per Thread context instead rather than fully global as seen here, one would then be able to do Request.withRequest(anotherRequestImpl, () -> { ... }) or similar.
Real world usually do not require the ThreadLocal approach and usually it is enough to be able to alter implementation for Test environment globally.
Note, that the only purpose for this is to enable a way to retain the ability to invoke methods DIRECTLY, EASILY and CLEANLY which static methods provides while at the same time be able to switch implementation should a desire arise at the cost of slightly more complex implementation.
It is just a pattern to get around having normally non modifiable static code.
An abstract method is defined only so that it can be overridden in a subclass. However, static methods can not be overridden. Therefore, it is a compile-time error to have an abstract, static method.
Now the next question is why static methods can not be overridden??
It's because static methods belongs to a particular class and not to its instance. If you try to override a static method you will not get any compilation or runtime error but compiler would just hide the static method of superclass.
A static method, by definition, doesn't need to know this. Thus, it cannot be a virtual method (that is overloaded according to dynamic subclass information available through this); instead, a static method overload is solely based on info available at compile time (this means: once you refer a static method of superclass, you call namely the superclass method, but never a subclass method).
According to this, abstract static methods would be quite useless because you will never have its reference substituted by some defined body.
I see that there are a god-zillion answers already but I don't see any practical solutions. Of course this is a real problem and there is no good reason for excluding this syntax in Java. Since the original question lacks a context where this may be need, I provide both a context and a solution:
Suppose you have a static method in a bunch of classes that are identical. These methods call a static method that is class specific:
class C1 {
static void doWork() {
...
for (int k: list)
doMoreWork(k);
...
}
private static void doMoreWork(int k) {
// code specific to class C1
}
}
class C2 {
static void doWork() {
...
for (int k: list)
doMoreWork(k);
...
}
private static void doMoreWork(int k) {
// code specific to class C2
}
}
doWork() methods in C1 and C2 are identical. There may be a lot of these calsses: C3 C4 etc. If static abstract was allowed, you'd eliminate the duplicate code by doing something like:
abstract class C {
static void doWork() {
...
for (int k: list)
doMoreWork(k);
...
}
static abstract void doMoreWork(int k);
}
class C1 extends C {
private static void doMoreWork(int k) {
// code for class C1
}
}
class C2 extends C {
private static void doMoreWork(int k) {
// code for class C2
}
}
but this would not compile because static abstract combination is not allowed.
However, this can be circumvented with static class construct, which is allowed:
abstract class C {
void doWork() {
...
for (int k: list)
doMoreWork(k);
...
}
abstract void doMoreWork(int k);
}
class C1 {
private static final C c = new C(){
#Override void doMoreWork(int k) {
System.out.println("code for C1");
}
};
public static void doWork() {
c.doWork();
}
}
class C2 {
private static final C c = new C() {
#Override void doMoreWork(int k) {
System.out.println("code for C2");
}
};
public static void doWork() {
c.doWork();
}
}
With this solution the only code that is duplicated is
public static void doWork() {
c.doWork();
}
Assume there are two classes, Parent and Child. Parent is abstract. The declarations are as follows:
abstract class Parent {
abstract void run();
}
class Child extends Parent {
void run() {}
}
This means that any instance of Parent must specify how run() is executed.
However, assume now that Parent is not abstract.
class Parent {
static void run() {}
}
This means that Parent.run() will execute the static method.
The definition of an abstract method is "A method that is declared but not implemented", which means it doesn't return anything itself.
The definition of a static method is "A method that returns the same value for the same parameters regardless of the instance on which it is called".
An abstract method's return value will change as the instance changes. A static method will not. A static abstract method is pretty much a method where the return value is constant, but does not return anything. This is a logical contradiction.
Also, there is really not much of a reason for a static abstract method.
An abstract class cannot have a static method because abstraction is done to achieve DYNAMIC BINDING while static methods are statically binded to their functionality.A static method means
behavior not dependent on an instance variable, so no instance/object
is required.Just the class.Static methods belongs to class and not object.
They are stored in a memory area known as PERMGEN from where it is shared with every object.
Methods in abstract class are dynamically binded to their functionality.
Declaring a method as static means we can call that method by its class name and if that class is abstract as well, it makes no sense to call it as it does not contain any body, and hence we cannot declare a method both as static and abstract.
As abstract methods belong to the class and cannot be overridden by the implementing class.Even if there is a static method with same signature , it hides the method ,does not override it.
So it is immaterial to declare the abstract method as static as it will never get the body.Thus, compile time error.
A static method can be called without an instance of the class. In your example you can call foo.bar2(), but not foo.bar(), because for bar you need an instance.
Following code would work:
foo var = new ImplementsFoo();
var.bar();
If you call a static method, it will be executed always the same code. In the above example, even if you redefine bar2 in ImplementsFoo, a call to var.bar2() would execute foo.bar2().
If bar2 now has no implementation (that's what abstract means), you can call a method without implementation. That's very harmful.
I believe I have found the answer to this question, in the form of why an interface's methods (which work like abstract methods in a parent class) can't be static. Here is the full answer (not mine)
Basically static methods can be bound at compile time, since to call them you need to specify a class. This is different than instance methods, for which the class of the reference from which you're calling the method may be unknown at compile time (thus which code block is called can only be determined at runtime).
If you're calling a static method, you already know the class where it's implemented, or any direct subclasses of it. If you define
abstract class Foo {
abstract static void bar();
}
class Foo2 {
#Override
static void bar() {}
}
Then any Foo.bar(); call is obviously illegal, and you will always use Foo2.bar();.
With this in mind, the only purpose of a static abstract method would be to enforce subclasses to implement such a method. You might initially think this is VERY wrong, but if you have a generic type parameter <E extends MySuperClass> it would be nice to guarantee via interface that E can .doSomething(). Keep in mind that due to type erasure generics only exist at compile time.
So, would it be useful? Yes, and maybe that is why Java 8 is allowing static methods in interfaces (though only with a default implementation). Why not abstract static methods with a default implementation in classes? Simply because an abstract method with a default implementation is actually a concrete method.
Why not abstract/interface static methods with no default implementation? Apparently, merely because of the way Java identifies which code block it has to execute (first part of my answer).
Because abstract class is an OOPS concept and static members are not the part of OOPS....
Now the thing is we can declare static complete methods in interface and we can execute interface by declaring main method inside an interface
interface Demo
{
public static void main(String [] args) {
System.out.println("I am from interface");
}
}
Because abstract mehods always need implementation by subclass.But if you make any method to static then overriding is not possible for this method
Example
abstract class foo {
abstract static void bar2();
}
class Bar extends foo {
//in this if you override foo class static method then it will give error
}
Static Method
A static method can be invoked without the need for creating an instance of a class.A static method belongs to the class rather than the object of a class.
A static method can access static data member and also it can change the value of it.
Abstract Keyword is used to implement abstraction.
A static method can't be overriden or implemented in child class. So, there is no use of making static method as abstract.
The idea of having an abstract static method would be that you can't use that particular abstract class directly for that method, but only the first derivative would be allowed to implement that static method (or for generics: the actual class of the generic you use).
That way, you could create for example a sortableObject abstract class or even interface
with (auto-)abstract static methods, which defines the parameters of sort options:
public interface SortableObject {
public [abstract] static String [] getSortableTypes();
public String getSortableValueByType(String type);
}
Now you can define a sortable object that can be sorted by the main types which are the same for all these objects:
public class MyDataObject implements SortableObject {
final static String [] SORT_TYPES = {
"Name","Date of Birth"
}
static long newDataIndex = 0L ;
String fullName ;
String sortableDate ;
long dataIndex = -1L ;
public MyDataObject(String name, int year, int month, int day) {
if(name == null || name.length() == 0) throw new IllegalArgumentException("Null/empty name not allowed.");
if(!validateDate(year,month,day)) throw new IllegalArgumentException("Date parameters do not compose a legal date.");
this.fullName = name ;
this.sortableDate = MyUtils.createSortableDate(year,month,day);
this.dataIndex = MyDataObject.newDataIndex++ ;
}
public String toString() {
return ""+this.dataIndex+". "this.fullName+" ("+this.sortableDate+")";
}
// override SortableObject
public static String [] getSortableTypes() { return SORT_TYPES ; }
public String getSortableValueByType(String type) {
int index = MyUtils.getStringArrayIndex(SORT_TYPES, type);
switch(index) {
case 0: return this.name ;
case 1: return this.sortableDate ;
}
return toString(); // in the order they were created when compared
}
}
Now you can create a
public class SortableList<T extends SortableObject>
that can retrieve the types, build a pop-up menu to select a type to sort on and resort the list by getting the data from that type, as well as hainv an add function that, when a sort type has been selected, can auto-sort new items in.
Note that the instance of SortableList can directly access the static method of "T":
String [] MenuItems = T.getSortableTypes();
The problem with having to use an instance is that the SortableList may not have items yet, but already need to provide the preferred sorting.
Cheerio,
Olaf.
First, a key point about abstract classes -
An abstract class cannot be instantiated (see wiki). So, you can't create any instance of an abstract class.
Now, the way java deals with static methods is by sharing the method with all the instances of that class.
So, If you can't instantiate a class, that class can't have abstract static methods since an abstract method begs to be extended.
Boom.
As per Java doc:
A static method is a method that is associated with the class in which
it is defined rather than with any object. Every instance of the class
shares its static methods
In Java 8, along with default methods static methods are also allowed in an interface. This makes it easier for us to organize helper methods in our libraries. We can keep static methods specific to an interface in the same interface rather than in a separate class.
A nice example of this is:
list.sort(ordering);
instead of
Collections.sort(list, ordering);
Another example of using static methods is also given in doc itself:
public interface TimeClient {
// ...
static public ZoneId getZoneId (String zoneString) {
try {
return ZoneId.of(zoneString);
} catch (DateTimeException e) {
System.err.println("Invalid time zone: " + zoneString +
"; using default time zone instead.");
return ZoneId.systemDefault();
}
}
default public ZonedDateTime getZonedDateTime(String zoneString) {
return ZonedDateTime.of(getLocalDateTime(), getZoneId(zoneString));
}
}
Because 'abstract' means the method is meant to be overridden and one can't override 'static' methods.
Regular methods can be abstract when they are meant to be overridden by subclasses and provided with functionality.
Imagine the class Foo is extended by Bar1, Bar2, Bar3 etc. So, each will have their own version of the abstract class according to their needs.
Now, static methods by definition belong to the class, they have nothing to do with the objects of the class or the objects of its subclasses. They don't even need them to exist, they can be used without instantiating the classes. Hence, they need to be ready-to-go and cannot depend on the subclasses to add functionality to them.
Because abstract is a keyword which is applied over Abstract methods do not specify a body. And If we talk about static keyword it belongs to class area.
because if you are using any static member or static variable in class it will load at class loading time.
There is one occurrence where static and abstract can be used together and that is when both of these modifiers are placed in front of a nested class.
In a single line, this dangerous combination (abstract + static) violates the object-oriented principle which is Polymorphism.
In an inheritance situation, the JVM will decide at runtime by the implementation in respect of the type of instance (runtime polymorphism) and not in respect of the type of reference variable (compile-time polymorphism).
With #Overriding:
Static methods do not support #overriding (runtime polymorphism), but only method hiding (compile-time polymorphism).
With #Hiding:
But in a situation of abstract static methods, the parent (abstract) class does not have implementation for the method. Hence, the child type reference is the only one available and it is not polymorphism.
Child reference is the only one available:
For this reason (suppress OOPs features), Java language considers abstract + static an illegal (dangerous) combination for methods.
You can do this with interfaces in Java 8.
This is the official documentation about it:
https://docs.oracle.com/javase/tutorial/java/IandI/defaultmethods.html
Because if a class extends an abstract class then it has to override abstract methods and that is mandatory. And since static methods are class methods resolved at compile time whereas overridden methods are instance methods resolved at runtime and following dynamic polymorphism.