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- Java 8 Interview Questions
- Multithreading Interview Questions
- Collections Interview Questions
- JDBC Interview Questions
- Java Programs
- Java String Methods
- JSP Interview Questions
- Servlets Interview Questions
- Java Multiple Choice Questions
- Spring Interview Questions
- Hibernate Interview Questions
- Java Design Pattern Questions
Exception is an error event that can happen during the execution of a program and disrupts its normal flow.
1. Checked Exception:
The classes which directly inherit Throwable class except RuntimeException and Error are known as checked exceptions e.g. IOException, SQLException etc. Checked exceptions are checked at compile-time.
2. Unchecked Exception:
The classes which inherit RuntimeException are known as unchecked exceptions e.g. ArithmeticException, NullPointerException, ArrayIndexOutOfBoundsException etc. Unchecked exceptions are not checked at compile-time, but they are checked at runtime.
3. Error:
Error is irrecoverable e.g. OutOfMemoryError, VirtualMachineError, AssertionError etc.
The java.lang.Throwable class is the root class of Java Exception hierarchy which is inherited by two subclasses: Exception and Error.
Example:
/**
* Exception classes
*/
import java.io.FileInputStream;
import java.io.FileNotFoundException;
import java.io.IOException;
import java.io.InputStream;
public class CustomExceptionExample {
public static void main(String[] args) throws MyException {
try {
processFile("file.txt");
} catch (MyException e) {
processErrorCodes(e);
}
}
private static void processErrorCodes(MyException e) throws MyException {
switch(e.getErrorCode()){
case "BAD_FILE_TYPE":
System.out.println("Bad File Type, notify user");
throw e;
case "FILE_NOT_FOUND_EXCEPTION":
System.out.println("File Not Found, notify user");
throw e;
case "FILE_CLOSE_EXCEPTION":
System.out.println("File Close failed, just log it.");
break;
default:
System.out.println("Unknown exception occured," +e.getMessage());
e.printStackTrace();
}
}
private static void processFile(String file) throws MyException {
InputStream fis = null;
try {
fis = new FileInputStream(file);
} catch (FileNotFoundException e) {
throw new MyException(e.getMessage(),"FILE_NOT_FOUND_EXCEPTION");
} finally {
try {
if(fis !=null) fis.close();
} catch (IOException e) {
throw new MyException(e.getMessage(),"FILE_CLOSE_EXCEPTION");
}
}
}
}
1. Aggregation:
We call aggregation those relationships whose objects have an independent lifecycle, but there is ownership, and child objects cannot belong to another parent object.
Example: Since Organization has Person as employees, the relationship between them is Aggregation. Here is how they look like in terms of Java classes
/**
* Aggregation
*/
public class Organization {
private List employees;
}
public class Person {
private String name;
}
2. Composition:
We use the term composition to refer to relationships whose objects don't have an independent lifecycle, and if the parent object is deleted, all child objects will also be deleted.
Example: Since Engine is-part-of Car, the relationship between them is Composition. Here is how they are implemented between Java classes.
/**
* Composition
*/
public class Car {
//final will make sure engine is initialized
private final Engine engine;
public Car(){
engine = new Engine();
}
}
class Engine {
private String type;
}
Aggregation | Composition |
---|---|
Aggregation is a weak Association. | Composition is a strong Association. |
Class can exist independently without owner. | Class can not meaningfully exist without owner. |
Have their own Life Time. | Life Time depends on the Owner. |
A uses B. | A owns B. |
Child is not owned by 1 owner. | Child can have only 1 owner. |
Has-A relationship. A has B. | Part-Of relationship. B is part of A. |
Denoted by a empty diamond in UML. | Denoted by a filled diamond in UML. |
We do not use "final" keyword for Aggregation. | "final" keyword is used to represent Composition. |
Examples: - Car has a Driver. - A Human uses Clothes. - A Company is an aggregation of People. - A Text Editor uses a File. - Mobile has a SIM Card. | Examples: - Engine is a part of Car. - A Human owns the Heart. - A Company is a composition of Accounts. - A Text Editor owns a Buffer. - IMEI Number is a part of a Mobile. |
Note: "final" keyword is used in Composition to make sure child variable is initialized.
1. Java Heap Space:
Java Heap space is used by java runtime to allocate memory to Objects and JRE classes. Whenever we create any object, it's always created in the Heap space.
Garbage Collection runs on the heap memory to free the memory used by objects that doesn't have any reference. Any object created in the heap space has global access and can be referenced from anywhere of the application.
2. Java Stack Memory:
Stack in java is a section of memory which contains methods, local variables and reference variables. Local variables are created in the stack.
Stack memory is always referenced in LIFO ( Last-In-First-Out ) order. Whenever a method is invoked, a new block is created in the stack memory for the method to hold local primitive values and reference to other objects in the method.
As soon as method ends, the block becomes unused and become available for next method. Stack memory size is very less compared to Heap memory.
Difference:
Parameter | Stack Memory | Heap Space |
---|---|---|
Application | Stack is used in parts, one at a time during execution of a thread | The entire application uses Heap space during runtime |
Size | Stack has size limits depending upon OS and is usually smaller then Heap | There is no size limit on Heap |
Storage | Stores only primitive variables and references to objects that are created in Heap Space | All the newly created objects are stored here |
Order | It is accessed using Last-in First-out (LIFO) memory allocation system | This memory is accessed via complex memory management techniques that include Young Generation, Old or Tenured Generation, and Permanent Generation. |
Life | Stack memory only exists as long as the current method is running | Heap space exists as long as the application runs |
Efficiency | Comparatively much faster to allocate when compared to heap | Slower to allocate when compared to stack |
Allocation/Deallocation | This Memory is automatically allocated and deallocated when a method is called and returned respectively | Heap space is allocated when new objects are created and deallocated by Gargabe Collector when they are no longer referenced |
Java Virtual Machine (JVM) is a specification that provides runtime environment in which java bytecode(.class files) can be executed. The JVM is the platform. The JVM acts as a "virtual" machine or processor. Java's platform independence consists mostly of its Java Virtual Machine (JVM). JVM makes this possible because it is aware of the specific instruction lengths and other particularities of the platform (Operating System).
The JVM is not platform independent. Java Virtual Machine (JVM) provides the environment to execute the java file(. Class file). So at the end it's depends on kernel and kernel is differ from OS (Operating System) to OS. The JVM is used to both translate the bytecode into the machine language for a particular computer and actually execute the corresponding machine-language instructions as well.
The Just-In-Time (JIT) compiler is a component of the runtime environment that improves the performance of Java applications by compiling bytecodes to native machine code at run time.
Java programs consists of classes, which contain platform-neutral bytecodes that can be interpreted by a JVM on many different computer architectures. At run time, the JVM loads the class files, determines the semantics of each individual bytecode, and performs the appropriate computation. The additional processor and memory usage during interpretation means that a Java application performs more slowly than a native application. The JIT compiler helps improve the performance of Java programs by compiling bytecodes into native machine code at run time. The JIT compiler is enabled by default. When a method has been compiled, the JVM calls the compiled code of that method directly instead of interpreting it.
The Java ClassLoader is a part of the Java Runtime Environment that dynamically loads Java classes into the Java Virtual Machine. Java code is compiled into class file by javac compiler and JVM executes Java program, by executing byte codes written in class file. ClassLoader is responsible for loading class files from file system, network or any other source.
Types of ClassLoader:
1. Bootstrap Class Loader:
It loads standard JDK class files from rt.jar and other core classes. It loads class files from jre/lib/rt.jar. For example, java.lang package class.
2. Extensions Class Loader:
It loads classes from the JDK extensions directly usually JAVA_HOME/lib/ext
directory or any other directory as java.ext.dirs.
3. System Class Loader:
It loads application specific classes from the CLASSPATH environment variable. It can be set while invoking program using -cp or classpath command line options.
1. JDK:
Java Development Kit is the core component of Java Environment and provides all the tools, executables and binaries required to compile, debug and execute a Java Program.
2. JVM:
JVM is responsible for converting Byte code to the machine specific code. JVM is also platform dependent and provides core java functions like memory management, garbage collection, security etc. JVM is customizable and we can use java options to customize it, for example allocating minimum and maximum memory to JVM. JVM is called virtual because it provides an interface that does not depend on the underlying operating system and machine hardware.
2. JRE:
Java Runtime Environment provides a platform to execute java programs. JRE consists of JVM and java binaries and other classes to execute any program successfully.
The Factory Method is usually categorised by a switch statement where each case returns a different class, using the same root interface so that the calling code never needs to make decisions about the implementation.
Example: credit card validator factory which returns a different validator for each card type.
/**
* Abstract Factory Pattern
*/
public ICardValidator GetCardValidator (string cardType)
{
switch (cardType.ToLower())
{
case "visa":
return new VisaCardValidator();
case "mastercard":
case "ecmc":
return new MastercardValidator();
default:
throw new CreditCardTypeException("Do not recognise this type");
}
}
Abstract Factory patterns work around a super-factory which creates other factories. This factory is also called as factory of factories. This type of design pattern comes under creational pattern as this pattern provides one of the best ways to create an object.
In Abstract Factory pattern an interface is responsible for creating a factory of related objects without explicitly specifying their classes. Each generated factory can give the objects as per the Factory pattern.
1. equals() and 2. hashcode()
Class inherits methods from the following classes in terms of HashMap
- java.util.AbstractMap
- java.util.Object
- java.util.Map
Nested Inner class can access any private instance variable of outer class. Like any other instance variable, we can have access modifier private, protected, public and default modifier.
Example:
/**
* Inner Class
*/
class Outer {
class Inner {
public void show() {
System.out.println("In a nested class method");
}
}
}
class Main {
public static void main(String[] args) {
Outer.Inner in = new Outer().new Inner();
in.show();
}
}
A subclass is class which inherits a method or methods from a superclass.
Example:
/**
* Sub Class
*/
class Car {
//...
}
class HybridCar extends Car {
//...
}
1. Static Class Loading:
Creating objects and instance using new
keyword is known as static class loading. The retrieval of class definition and instantiation of the object is done at compile time.
Example:
/**
* Static Class Loading
*/
class TestClass {
public static void main(String args[]) {
TestClass tc = new TestClass();
}
}
2. Dynamic Class Loading:
Loading classes use Class.forName()
method. Dynamic class loading is done when the name of the class is not known at compile time.
Example:
/**
* Dynamic Class Loading
*/
Class.forName (String className);
1. Transient:
The transient modifier tells the Java object serialization subsystem to exclude the field when serializing an instance of the class. When the object is then deserialized, the field will be initialized to the default value; i.e. null for a reference type, and zero or false for a primitive type.
Example:
/**
* Transient
*/
public transient int limit = 55; // will not persist
public int b; // will persist
2. Volatile:
The volatile modifier tells the JVM that writes to the field should always be synchronously flushed to memory, and that reads of the field should always read from memory. This means that fields marked as volatile can be safely accessed and updated in a multi-thread application without using native or standard library-based synchronization.
Example:
/**
* Volatile
*/
public class MyRunnable implements Runnable {
private volatile boolean active;
public void run() {
active = true;
while (active) {
}
}
public void stop() {
active = false;
}
}
JVM is a program which takes Java bytecode and converts the byte code (line by line) into machine understandable code. JVM perform some particular types of operations:
- Loading of code
- Verification of code
- Executing the code
- It provide run-time environment to the users
Types of Memory areas allocated by the JVM:
1. Classloader: Classloader is a subsystem of JVM that is used to load class files.
2. Class(Method) Area: Class(Method) Area stores per-class structures such as the runtime constant pool, field and method data, the code for methods.
3. Heap: It is the runtime data area in which objects are allocated.
4. Stack: Java Stack stores frames.It holds local variables and partial results, and plays a part in method invocation and return. Each thread has a private JVM stack, created at the same time as thread.
5. Program Counter Register: PC (program counter) register. It contains the address of the Java virtual machine instruction currently being executed.
6. Native Method Stack: It contains all the native methods used in the application.
Java constructor chaining is a method of calling one constructor with the help of another while considering the present object. It can be done in 2 ways –
- Within same class: It can be done using
this()
keyword for constructors in the same class. - From base class: By using
super()
keyword to call a constructor from the base class.
/**
* Constructor Chaining
* within same class Using this() keyword
*/
class Temp
{
// default constructor 1
// default constructor will call another constructor
// using this keyword from same class
Temp() {
// calls constructor 2
this(5);
System.out.println("The Default constructor");
}
// parameterized constructor 2
Temp(int x) {
// calls constructor 3
this(10, 20);
System.out.println(x);
}
// parameterized constructor 3
Temp(int x, int y) {
System.out.println(10 + 20);
}
public static void main(String args[]) {
// invokes default constructor first
new Temp();
}
}
Ouput:
30
10
The Default constructor
/**
* Constructor Chaining to
* other class using super() keyword
*/
class Base
{
String name;
// constructor 1
Base() {
this("");
System.out.println("No-argument constructor of base class");
}
// constructor 2
Base(String name) {
this.name = name;
System.out.println("Calling parameterized constructor of base");
}
}
class Derived extends Base
{
// constructor 3
Derived() {
System.out.println("No-argument constructor of derived");
}
// parameterized constructor 4
Derived(String name) {
// invokes base class constructor 2
super(name);
System.out.println("Calling parameterized constructor of derived");
}
public static void main(String args[]) {
// calls parameterized constructor 4
Derived obj = new Derived("test");
// Calls No-argument constructor
// Derived obj = new Derived();
}
}
Output:
Calling parameterized constructor of base
Calling parameterized constructor of derived
Yes. We can declare main method as final. But, In inheritance concept we cannot declare main method as final in parent class. It give compile time error.
The main method has to be public because it has to be called by JVM which is outside the scope of the package and hence would need the access specifier-public.
Example:
public class Test {
public final static void main(String[] args) throws Exception {
System.out.println("This is Test Class");
}
}
class Child extends Test {
public static void main(String[] args) throws Exception {
System.out.println("This is Child Class");
}
}
Output
Cannot override the final method from Test.
There are two types of polymorphism in java:
- Static Polymorphism also known as Compile time polymorphism
- Runtime polymorphism also known as Dynamic Polymorphism
1. Static Polymorphism:
Method overloading is one of the way java supports static polymorphism. Here we have two definitions of the same method add() which add method would be called is determined by the parameter list at the compile time. That is the reason this is also known as compile time polymorphism.
Example:
/**
* Static Polymorphism
*/
class SimpleCalculator {
int add(int a, int b) {
return a + b;
}
int add(int a, int b, int c) {
return a + b + c;
}
}
public class Demo {
public static void main(String args[]) {
SimpleCalculator obj = new SimpleCalculator();
System.out.println(obj.add(10, 20));
System.out.println(obj.add(10, 20, 30));
}
}
Output
30
60
2. Runtime Polymorphism:
It is also known as Dynamic Method Dispatch. Dynamic polymorphism is a process in which a call to an overridden method is resolved at runtime, thats why it is called runtime polymorphism.
Example:
/**
* Runtime Polymorphism
*/
class ABC {
public void myMethod() {
System.out.println("Overridden Method");
}
}
public class XYZ extends ABC {
public void myMethod() {
System.out.println("Overriding Method");
}
public static void main(String args[]) {
ABC obj = new XYZ();
obj.myMethod();
}
}
Output:
Overriding Method
In Java, all non-static methods are by default virtual functions. Only methods marked with the keyword final
, which cannot be overridden, along with private methods
, which are not inherited, are non-virtual.
Example: Virtual function with Interface
/**
* The function applyBrakes() is virtual because
* functions in interfaces are designed to be overridden.
**/
interface Bicycle {
void applyBrakes();
}
class ACMEBicycle implements Bicycle {
public void applyBrakes() { // Here we implement applyBrakes()
System.out.println("Brakes applied"); // function
}
}
It is possible to have different return type for a overriding method in child class, but child's return type should be sub-type of parent's return type. Overriding method becomes variant with respect to return type. The covariant return type specifies that the return type may vary in the same direction as the subclass.
Example:
/**
* Covariant Return Type
*/
class SuperClass {
SuperClass get() {
System.out.println("SuperClass");
return this;
}
}
public class Tester extends SuperClass {
Tester get() {
System.out.println("SubClass");
return this;
}
public static void main(String[] args) {
SuperClass tester = new Tester();
tester.get();
}
}
Output:
Subclass
In Java, Abstraction is supported using interface
and abstract class
while Encapsulation is supported using access modifiers e.g. public, private and protected. Abstraction solves the problem at design level while Encapsulation solves it implementation level.
Abstraction is about hiding unwanted details while giving out most essential details, while Encapsulation means hiding the code and data into a single unit e.g. class or method to protect inner working of an object from outside world.
Difference:
Abstraction | Encapsulation |
---|---|
Abstraction is a process of hiding the implementation details and showing only functionality to the user. | Encapsulation is a process of wrapping code and data together into a single unit |
Abstraction lets you focus on what the object does instead of how it does it. | Encapsulation provides you the control over the data and keeping it safe from outside misuse. |
Abstraction solves the problem in the Design Level. | Encapsulation solves the problem in the Implementation Level. |
Abstraction is implemented by using Interfaces and Abstract Classes. | Encapsulation is implemented by using Access Modifiers (private, default, protected, public) |
Abstraction means hiding implementation complexities by using interfaces and abstract class. | Encapsulation means hiding data by using setters and getters. |
The java compiler adds public and abstract keywords before the interface method and public, static and final keyword before data members automatically
public interface Test {
public string name1;
private String email;
protected pass;
}
as you have declare variable in test interface with private and protected it will give error. if you do not specify the modifier the compiler will add public static final automatically.
public interface Test {
public static final string name1;
public static final String email;
public static final pass;
}
- Interfaces cannot be instantiated that is why the variable are static
- Interface are used to achieve the 100% abstraction there for the variable are final
- An interface provide a way for the client to interact with the object. If variables were not public, the clients would not have access to them. that is why variable are public
An interface reference can point to any object of a class that implements this interface
/**
* Interface
*/
interface MyInterface {
void display();
}
public class TestInterface implements MyInterface {
void display() {
System.out.println("Hello World");
}
public static void main(String[] args) {
MyInterface myInterface = new TestInterface();
MyInterface.display();
}
}
A stream can be defined as a sequence of data. There are two kinds of Streams −
- InPutStream − The InputStream is used to read data from a source.
- OutPutStream − The OutputStream is used for writing data to a destination.
1. Byte Streams:
Java byte streams are used to perform input and output of 8-bit bytes. Though there are many classes related to byte streams but the most frequently used classes are, FileInputStream and FileOutputStream.
Example:
/**
* Byte Streams
*/
import java.io.*;
public class CopyFile {
public static void main(String args[]) throws IOException {
FileInputStream in = null;
FileOutputStream out = null;
try {
in = new FileInputStream("input.txt");
out = new FileOutputStream("output.txt");
int c;
while ((c = in.read()) != -1) {
out.write(c);
}
} finally {
if (in != null) {
in.close();
}
if (out != null) {
out.close();
}
}
}
}
2. Character Streams:
Java Character streams are used to perform input and output for 16-bit unicode. Though there are many classes related to character streams but the most frequently used classes are, FileReader and FileWriter.
Example:
/**
* Character Streams
*/
import java.io.*;
public class CopyFile {
public static void main(String args[]) throws IOException {
FileReader in = null;
FileWriter out = null;
try {
in = new FileReader("input.txt");
out = new FileWriter("output.txt");
int c;
while ((c = in.read()) != -1) {
out.write(c);
}
} finally {
if (in != null) {
in.close();
}
if (out != null) {
out.close();
}
}
}
}
1. Runtime Class:
The java.lang.Runtime class is a subclass of Object class, provide access to the Java runtime system. The runtime information like memory availability, invoking the garbage collector, etc.
Example:
/**
* Runtime Class
*/
public class RuntimeTest
{
static class Message extends Thread {
public void run() {
System.out.println(" Exit");
}
}
public static void main(String[] args) {
try {
Runtime.getRuntime().addShutdownHook(new Message());
System.out.println(" Program Started...");
System.out.println(" Wait for 5 seconds...");
Thread.sleep(5000);
System.out.println(" Program Ended...");
} catch (Exception e) {
e.printStackTrace();
}
}
}
2. System Class:
The purpose of the System class is to provide access to system resources. It contains accessibility to standard input, standart output, error output streams, current time in millis, terminating the application, etc.
An assertion allows testing the correctness of any assumptions that have been made in the program. Assertion is achieved using the assert statement in Java.
While executing assertion, it is believed to be true. If it fails, JVM throws an error named AssertionError
. It is mainly used for testing purposes during development.
The assert statement is used with a Boolean expression and can be written in two different ways.
// First way
assert expression;
// Second way
assert expression1 : expression2;
Example:
/**
* Assertions
*/
public class Example {
public static void main(String[] args) {
int age = 14;
assert age <= 18 : "Cannot Vote";
System.out.println("The voter's age is " + age);
}
}
Abstract class and interface both are used to achieve abstraction where we can declare the abstract methods. Abstract class and interface both can't be instantiated.
Abstract Class | Interface |
---|---|
Abstract class can have abstract and non-abstract methods. | Interface can have only abstract methods. Since Java 8, it can have default and static methods also. |
Abstract class doesn't support multiple inheritance. | Interface supports multiple inheritance. |
Abstract class can have final, non-final, static and non-static variables. | Interface has only static and final variables. |
Abstract class can provide the implementation of interface. | Interface can't provide the implementation of abstract class. |
An abstract class can extend another Java class and implement multiple Java interfaces. | An interface can extend another Java interface only. |
An abstract class can be extended using keyword "extends". | An interface can be implemented using keyword "implements". |
A Java abstract class can have class members like private, protected, etc. | Members of a Java interface are public by default. |
The wrapper class in Java provides the mechanism to convert primitive into object and object into primitive.
Use of Wrapper classes in Java:
-
Change the value in Method: Java supports only call by value. So, if we pass a primitive value, it will not change the original value. But, if we convert the primitive value in an object, it will change the original value.
-
Serialization: We need to convert the objects into streams to perform the serialization. If we have a primitive value, we can convert it in objects through the wrapper classes.
-
Synchronization: Java synchronization works with objects in Multithreading.
-
java.util package: The java.util package provides the utility classes to deal with objects.
-
Collection Framework: Java collection framework works with objects only. All classes of the collection framework (ArrayList, LinkedList, Vector, HashSet, LinkedHashSet, TreeSet, PriorityQueue, ArrayDeque, etc.) deal with objects only.
Sl.No | Primitive Type | Wrapper class |
---|---|---|
01. | boolean | Boolean |
02. | char | Character |
03. | byte | Byte |
04. | short | Short |
05. | int | Integer |
06. | long | Long |
07. | float | Float |
08. | double | Double |
Example: Primitive to Wrapper
/**
* Java program to convert primitive into objects
* Autoboxing example of int to Integer
*/
class WrapperExample {
public static void main(String args[]) {
int a = 20;
Integer i = Integer.valueOf(a); // converting int into Integer explicitly
Integer j = a; // autoboxing, now compiler will write Integer.valueOf(a) internally
System.out.println(a + " " + i + " " + j);
}
}
Output
20 20 20
Reflection API in Java is used to manipulate class and its members which include fields, methods, constructor, etc. at runtime.
The java.lang.Class class provides many methods that can be used to get metadata, examine and change the run time behavior of a class. There are 3 ways to get the instance of Class class.
- forName() method of Class class
- getClass() method of Object class
- the .class syntax
1. forName() method:
- is used to load the class dynamically.
- returns the instance of Class class.
- It should be used if you know the fully qualified name of class.This cannot be used for primitive types.
/**
* forName()
*/
class Simple {
}
class Test {
public static void main(String args[]) {
Class c = Class.forName("Simple");
System.out.println(c.getName());
}
}
Output
Simple
2. getClass() method:
It returns the instance of Class class. It should be used if you know the type. Moreover, it can be used with primitives.
/**
* getClass
*/
class Simple {
}
class Test {
void printName(Object obj) {
Class c = obj.getClass();
System.out.println(c.getName());
}
public static void main(String args[]) {
Simple s = new Simple();
Test t = new Test();
t.printName(s);
}
}
Output
Simple
3. The .class syntax:
If a type is available but there is no instance then it is possible to obtain a Class by appending ".class" to the name of the type. It can be used for primitive data type also.
/**
* .class Syntax
*/
class Test {
public static void main(String args[]) {
Class c = boolean.class;
System.out.println(c.getName());
Class c2 = Test.class;
System.out.println(c2.getName());
}
}
Output
boolean
Test
In Java, a constructor is a block of codes similar to the method. It is called when an instance of the class is created. At the time of calling constructor, memory for the object is allocated in the memory.
Types of Java Constructors:
- Default Constructor (or) no-arg Constructor
- Parameterized Constructor
Example: Default Constructor (or) no-arg constructor
/**
* Default Constructor
*/
public class Car {
Car() {
System.out.println("Default Constructor of Car class called");
}
public static void main(String args[]) {
// Calling the default constructor
Car c = new Car();
}
}
Output
Default Constructor of Car class called
Example: Parameterized Constructor
/**
* Parameterized Constructor
*/
public class Car {
String carColor;
Car(String carColor) {
this.carColor = carColor;
}
public void display() {
System.out.println("Color of the Car is : " + carColor);
}
public static void main(String args[]) {
// Calling the parameterized constructor
Car c = new Car("Blue");
c.display();
}
}
If a method is declared as static, it is a member of a class rather than belonging to the object of the class. It can be called without creating an object of the class. A static method also has the power to access static data members of the class.
There are a few restrictions imposed on a static method
- The static method cannot use non-static data member or invoke non-static method directly.
- The
this
andsuper
cannot be used in static context. - The static method can access only static type data ( static type instance variable ).
- There is no need to create an object of the class to invoke the static method.
- A static method cannot be overridden in a subclass
Example:
/**
* Static Methods
*/
class Parent {
static void display() {
System.out.println("Super class");
}
}
public class Example extends Parent {
void display() // trying to override display() {
System.out.println("Sub class");
}
public static void main(String[] args) {
Parent obj = new Example();
obj.display();
}
}
This generates a compile time error. The output is as follows −
Example.java:10: error: display() in Example cannot override display() in Parent
void display() // trying to override display()
^
overridden method is static
1 error
1. Final Variable:
Final variables are nothing but constants. We cannot change the value of a final variable once it is initialized.
Example:
/**
* Final Variable
*/
class Demo {
final int MAX_VALUE = 99;
void myMethod() {
MAX_VALUE = 101;
}
public static void main(String args[]) {
Demo obj = new Demo();
obj.myMethod();
}
}
Output
Exception in thread "main" java.lang.Error: Unresolved compilation problem:
The final field Demo.MAX_VALUE cannot be assigned
at beginnersbook.com.Demo.myMethod(Details.java:6)
at beginnersbook.com.Demo.main(Details.java:10)
2. Blank final variable:
A final variable that is not initialized at the time of declaration is known as blank final variable. We must initialize the blank final variable in constructor of the class otherwise it will throw a compilation error ( Error: variable MAX_VALUE might not have been initialized
).
Example:
/**
* Blank final variable
*/
class Demo {
// Blank final variable
final int MAX_VALUE;
Demo() {
// It must be initialized in constructor
MAX_VALUE = 100;
}
void myMethod() {
System.out.println(MAX_VALUE);
}
public static void main(String args[]) {
Demo obj = new Demo();
obj.myMethod();
}
}
Output
100
3. Final Method:
A final method cannot be overridden. Which means even though a sub class can call the final method of parent class without any issues but it cannot override it.
Example:
/**
* Final Method
*/
class XYZ {
final void demo() {
System.out.println("XYZ Class Method");
}
}
class ABC extends XYZ {
void demo() {
System.out.println("ABC Class Method");
}
public static void main(String args[]) {
ABC obj = new ABC();
obj.demo();
}
}
The static import feature of Java 5 facilitate the java programmer to access any static member of a class directly. There is no need to qualify it by the class name.
/**
* Static Import
*/
import static java.lang.System.*;
class StaticImportExample {
public static void main(String args[]) {
out.println("Hello");// Now no need of System.out
out.println("Java");
}
}
The Java Regex or Regular Expression is an API to define a pattern for searching or manipulating strings.
Regular Expression Package:
- MatchResult interface
- Matcher class
- Pattern class
- PatternSyntaxException class
Example:
/**
* Regular Expression
*/
import java.util.regex.*;
public class Index {
public static void main(String args[]) {
// Pattern, String
boolean b = Pattern.matches(".s", "as");
System.out.println("Match: " + b);
}
}
In java, external process can be invoked using exec() method of Runtime Class.
Example:
/**
* exec()
*/
import java.io.IOException;
class ExternalProcessExample {
public static void main(String[] args) {
try {
// Command to create an external process
String command = "C:\\Program Files (x86)\\Google\\Chrome\\Application\\chrome.exe";
// Running the above command
Runtime run = Runtime.getRuntime();
Process proc = run.exec(command);
} catch (IOException e) {
e.printStackTrace();
}
}
}
BufferedInputStream
and BufferedOutputStream
class is used for buffering an input and output stream while reading and writing, respectively. It internally uses buffer to store data. It adds more efficiency than to write data directly into a stream. So, it makes the performance fast.
Example:
/**
* BufferedInputStream
*/
import java.io.BufferedInputStream;
import java.io.File;
import java.io.FileInputStream;
import java.io.IOException;
public class BufferedInputStreamExample {
public static void main(String[] args) {
File file = new File("file.txt");
FileInputStream fileInputStream = null;
BufferedInputStream bufferedInputStream = null;
try {
fileInputStream = new FileInputStream(file);
bufferedInputStream = new BufferedInputStream(fileInputStream);
// Create buffer
byte[] buffer = new byte[1024];
int bytesRead = 0;
while ((bytesRead = bufferedInputStream.read(buffer)) != -1) {
System.out.println(new String(buffer, 0, bytesRead));
}
} catch (IOException e) {
e.printStackTrace();
} finally {
try {
if (fileInputStream != null) {
fileInputStream.close();
}
if (bufferedInputStream != null) {
bufferedInputStream.close();
}
} catch (IOException e) {
e.printStackTrace();
}
}
}
}
Output
This is an example of reading data from file
Example:
/**
* BufferedOutputStream
*/
import java.io.BufferedOutputStream;
import java.io.File;
import java.io.FileOutputStream;
import java.io.IOException;
public class BufferedOutputStreamExample {
public static void main(String[] args) {
File file = new File("outfile.txt");
FileOutputStream fileOutputStream = null;
BufferedOutputStream bufferedOutputStream = null;
try {
fileOutputStream = new FileOutputStream(file);
bufferedOutputStream = new BufferedOutputStream(fileOutputStream);
bufferedOutputStream.write("This is an example of writing data to a file".getBytes());
bufferedOutputStream.flush();
} catch (IOException e) {
e.printStackTrace();
} finally {
try {
if (fileOutputStream != null) {
fileOutputStream.close();
}
if (bufferedOutputStream != null) {
bufferedOutputStream.close();
}
} catch (IOException e) {
e.printStackTrace();
}
}
}
}
Output
This is an example of writing data to a file
Java 7 has introduced PosixFilePermission Enum and java.nio.file.Files includes a method setPosixFilePermissions( Path path, Set<PosixFilePermission> perms
) that can be used to set file permissions easily.
Example:
/**
* FilePermissions
*/
import java.io.File;
import java.io.IOException;
import java.nio.file.Files;
import java.nio.file.Paths;
import java.nio.file.attribute.PosixFilePermission;
import java.util.HashSet;
import java.util.Set;
public class FilePermissions {
public static void main(String[] args) throws IOException {
File file = new File("/Users/file.txt");
// change permission to 777 for all the users
// no option for group and others
file.setExecutable(true, false);
file.setReadable(true, false);
file.setWritable(true, false);
// using PosixFilePermission to set file permissions 777
Set<PosixFilePermission> perms = new HashSet<PosixFilePermission>();
// add owners permission
perms.add(PosixFilePermission.OWNER_READ);
perms.add(PosixFilePermission.OWNER_WRITE);
perms.add(PosixFilePermission.OWNER_EXECUTE);
// add group permissions
perms.add(PosixFilePermission.GROUP_READ);
perms.add(PosixFilePermission.GROUP_WRITE);
perms.add(PosixFilePermission.GROUP_EXECUTE);
// add others permissions
perms.add(PosixFilePermission.OTHERS_READ);
perms.add(PosixFilePermission.OTHERS_WRITE);
perms.add(PosixFilePermission.OTHERS_EXECUTE);
Files.setPosixFilePermissions(Paths.get("/Users/run.sh"), perms);
}
}
In Java, there are three different ways for reading input from the user in the command line environment ( console ).
1. Using Buffered Reader Class:
This method is used by wrapping the System.in ( standard input stream ) in an InputStreamReader which is wrapped in a BufferedReader, we can read input from the user in the command line.
/**
* Buffered Reader Class
*/
import java.io.BufferedReader;
import java.io.IOException;
import java.io.InputStreamReader;
public class Test {
public static void main(String[] args) throws IOException {
// Enter data using BufferReader
BufferedReader reader = new BufferedReader(new InputStreamReader(System.in));
// Reading data using readLine
String name = reader.readLine();
// Printing the read line
System.out.println(name);
}
}
2. Using Scanner Class:
The main purpose of the Scanner class is to parse primitive types and strings using regular expressions, however it is also can be used to read input from the user in the command line.
/**
* Scanner Class
*/
import java.util.Scanner;
class GetInputFromUser {
public static void main(String args[]) {
// Using Scanner for Getting Input from User
Scanner in = new Scanner(System.in);
String s = in.nextLine();
System.out.println("You entered string " + s);
int a = in.nextInt();
System.out.println("You entered integer " + a);
float b = in.nextFloat();
System.out.println("You entered float " + b);
}
}
3. Using Console Class:
It has been becoming a preferred way for reading user's input from the command line. In addition, it can be used for reading password-like input without echoing the characters entered by the user; the format string syntax can also be used ( like System.out.printf() ).
/**
* Console Class
*/
public class Sample {
public static void main(String[] args) {
// Using Console to input data from user
String name = System.console().readLine();
System.out.println(name);
}
}
Q. How can you avoid serialization in child class if the base class is implementing the Serializable interface?
If superClass has implemented Serializable that means subclass is also Serializable ( as subclass always inherits all features from its parent class ), for avoiding Serialization in sub-class we can define writeObject() method and throw NotSerializableException() from there as done below.
/**
* Serialization
*/
import java.io.FileOutputStream;
import java.io.IOException;
import java.io.NotSerializableException;
import java.io.ObjectOutput;
import java.io.ObjectOutputStream;
import java.io.OutputStream;
import java.io.Serializable;
class Super implements Serializable {
private static final long serialVersionUID = 1L;
}
class Sub extends Super {
private static final long serialVersionUID = 1L;
private Integer id;
public Sub(Integer id) {
this.id = id;
}
@Override
public String toString() {
return "Employee [id=" + id + "]";
}
/*
* define how Serialization process will write objects.
*/
private void writeObject(ObjectOutputStream os) throws NotSerializableException {
throw new NotSerializableException("This class cannot be Serialized");
}
}
public class SerializeDeserialize {
public static void main(String[] args) {
Sub object1 = new Sub(8);
try {
OutputStream fout = new FileOutputStream("ser.txt");
ObjectOutput oout = new ObjectOutputStream(fout);
System.out.println("Serialization process has started, serializing objects...");
oout.writeObject(object1);
fout.close();
oout.close();
System.out.println("Object Serialization completed.");
} catch (IOException e) {
e.printStackTrace();
}
}
}
Output
Serialization process has started, serializing objects...
java.io.NotSerializableException: This class cannot be Serialized
at SerDeser11throwNotSerExc.Sub.writeObject(SerializeConstructorCheck.java:35)
at sun.reflect.NativeMethodAccessorImpl.invoke0(Native Method)
at sun.reflect.NativeMethodAccessorImpl.invoke(Unknown Source)
at sun.reflect.DelegatingMethodAccessorImpl.invoke(Unknown Source)
at java.lang.reflect.Method.invoke(Unknown Source)
at java.io.ObjectStreamClass.invokeWriteObject(Unknown Source)
at java.io.ObjectOutputStream.writeSerialData(Unknown Source)
at java.io.ObjectOutputStream.writeOrdinaryObject(Unknown Source)
at java.io.ObjectOutputStream.writeObject0(Unknown Source)
at java.io.ObjectOutputStream.writeObject(Unknown Source)
at SerDeser11throwNotSerExc.SerializeConstructorCheck.main(SerializeConstructorCheck.java:51)
SERIALIZABLE | EXTERNALIZABLE |
---|---|
Serializable is a marker interface i.e. does not contain any method. | Externalizable interface contains two methods writeExternal() and readExternal() which implementing classes MUST override. |
Serializable interface pass the responsibility of serialization to JVM and it's default algorithm. | Externalizable provides control of serialization logic to programmer – to write custom logic. |
Mostly, default serialization is easy to implement, but has higher performance cost. | Serialization done using Externalizable, add more responsibility to programmer but often result in better performance. |
It's hard to analyze and modify class structure because any change may break the serialization. | It's more easy to analyze and modify class structure because of complete control over serialization logic. |
Default serialization does not call any class constructor. | A public no-arg constructor is required while using Externalizable interface. |
1. Using new keyword:
MyObject object = new MyObject();
2. Using Class.forName():
MyObject object = (MyObject) Class.forName("subin.rnd.MyObject").newInstance();
3. Using clone():
MyObject anotherObject = new MyObject();
MyObject object = (MyObject) anotherObject.clone();
4. Using object deserialization:
ObjectInputStream inStream = new ObjectInputStream(anInputStream );
MyObject object = (MyObject) inStream.readObject();
The javap command displays information about the fields, constructors and methods present in a class file. The javap command ( also known as the Java Disassembler ) disassembles one or more class files.
/**
* Java Disassembler
*/
class Simple {
public static void main(String args[]) {
System.out.println("Hello World");
}
}
cmd> javap Simple.class
Output
Compiled from ".java"
class Simple {
Simple();
public static void main(java.lang.String[]);
}
The automatic conversion of primitive data types into its equivalent Wrapper type is known as boxing and opposite operation is known as unboxing.
Example: Autoboxing
/**
* Autoboxing
*/
class BoxingExample {
public static void main(String args[]) {
int a = 50;
Integer a2 = new Integer(a); // Boxing
Integer a3 = 5; // Boxing
System.out.println(a2 + " " + a3);
}
}
Example: Unboxing
/**
* Unboxing
*/
class UnboxingExample {
public static void main(String args[]) {
Integer i = new Integer(50);
int a = i;
System.out.println(a);
}
}
A native method is a Java method (either an instance method or a class method) whose implementation is also written in another programming language such as C/C++. Moreover, a method marked as native cannot have a body and should end with a semicolon:
Main.java:
public class Main {
public native int intMethod(int i);
public static void main(String[] args) {
System.loadLibrary("Main");
System.out.println(new Main().intMethod(2));
}
}
Main.c:
#include <jni.h>
#include "Main.h"
JNIEXPORT jint JNICALL Java_Main_intMethod(
JNIEnv *env, jobject obj, jint i) {
return i * i;
}
Compile and Run:
javac Main.java
javah -jni Main
gcc -shared -fpic -o libMain.so -I${JAVA_HOME}/include \
-I${JAVA_HOME}/include/linux Main.c
java -Djava.library.path=. Main
Output
4
Immutable objects are objects that don't change. A Java immutable object must have all its fields be internal, private final fields. It must not implement any setters. It needs a constructor that takes a value for every single field.
Creating an Immutable Object:
- Do not add any setter method
- Declare all fields final and private
- If a field is a mutable object create defensive copies of it for getter methods
- If a mutable object passed to the constructor must be assigned to a field create a defensive copy of it
- Don't allow subclasses to override methods.
/**
* Immutable Object
*/
public class DateContainer {
private final Date date;
public DateContainer() {
this.date = new Date();
}
public Date getDate() {
return new Date(date.getTime());
}
}
Though both Inheritance and Composition provides code reusablility, main difference between Composition and Inheritance in Java is that Composition allows reuse of code without extending it but for Inheritance you must extend the class for any reuse of code or functionality. Inheritance is an "is-a" relationship. Composition is a "has-a".
Example: Inheritance
/**
* Inheritance
*/
class Fruit {
// ...
}
class Apple extends Fruit {
// ...
}
Example: Composition
/**
* Composition
*/
class Fruit {
// ...
}
class Apple {
private Fruit fruit = new Fruit();
// ...
}
DOM and SAX parser are extensively used to read and parse XML file in java and have their own set of advantage and disadvantage.
DOM (Document Object Model) | Parser SAX (Simple API for XML) Parser | |
---|---|---|
Abbreviation | DOM stands for Document Object Model | SAX stands for Simple API for XML Parsing |
type | Load entire memory and keep in tree structure | event based parser |
size of Document | good for smaller size | good to choose for larger size of file. |
Load | Load entire document in memory | does not load entire document. |
suitable | better suitable for smaller and efficient memory | SAX is suitable for larger XML doc |
When you create String object using new()
operator, it always create a new object in heap memory. On the other hand, if you create object using String literal syntax e.g. "Java", it may return an existing object from String pool ( a cache of String object in Perm gen space, which is now moved to heap space in recent Java release ), if it's already exists. Otherwise it will create a new string object and put in string pool for future re-use.
Example:
/**
* String literal
*/
String a = "abc";
String b = "abc";
System.out.println(a == b); // true
/**
* Using new()
*/
String c = new String("abc");
String d = new String("abc");
System.out.println(c == d); // false
Immutable class means that once an object is created, we cannot change its content. In Java, all the wrapper classes (like Integer, Boolean, Byte, Short) and String class is immutable.
Rules to create immutable classes:
- The class must be declared as final
- Data members in the class must be declared as final
- A parameterized constructor
- Getter method for all the variables in it
- No setters
/**
* Immutable Class
*/
public final class Employee {
final String pancardNumber;
public Employee(String pancardNumber) {
this.pancardNumber = pancardNumber;
}
public String getPancardNumber() {
return pancardNumber;
}
}
1. Mutability Difference:
String
is immutable, if you try to alter their values, another object gets created, whereas StringBuffer
and StringBuilder
are mutable so they can change their values.
2. Thread-Safety Difference:
The difference between StringBuffer
and StringBuilder
is that StringBuffer is thread-safe. So when the application needs to be run only in a single thread then it is better to use StringBuilder. StringBuilder is more efficient than StringBuffer.
Example:
/**
* StringBuffer
*/
public class BufferTest {
public static void main(String[] args) {
StringBuffer buffer = new StringBuffer("Hello");
buffer.append(" World");
System.out.println(buffer);
}
}
Example:
/**
* StringBuilder
*/
public class BuilderTest {
public static void main(String[] args) {
StringBuilder builder = new StringBuilder("Hello");
builder.append(" World");
System.out.println(builder);
}
}
The standard definition of a memory leak is a scenario that occurs when objects are no longer being used by the application, but the Garbage Collector is unable to remove them from working memory – because they're still being referenced. As a result, the application consumes more and more resources – which eventually leads to a fatal OutOfMemoryError.
Some tools that do memory management to identifies useless objects or memeory leaks like:
Example:
/**
* Memory Leaks
*/
import java.util.Vector;
public class MemoryLeaksExample {
public static void main(String[] args) {
Vector v = new Vector(214444);
Vector v1 = new Vector(214744444);
Vector v2 = new Vector(214444);
System.out.println("Memory Leaks Example");
}
}
Output
Exception in thread "main" java.lang.OutOfMemoryError: Java heap space exceed
Types of Memory Leaks in Java:
- Memory Leak through static Fields
- Unclosed Resources/connections
- Adding Objects With no
hashCode()
andequals()
Into a HashSet - Inner Classes that Reference Outer Classes
- Through
finalize()
Methods - Calling
String.intern()
on Long String
BASIS FOR COMPARISON | ERROR | EXCEPTION |
---|---|---|
Basic | An error is caused due to lack of system resources. | An exception is caused because of the code. |
Recovery | An error is irrecoverable. | An exception is recoverable. |
Keywords | There is no means to handle an error by the program code. | Exceptions are handled using three keywords "try", "catch", and "throw". |
Consequences | As the error is detected the program will terminated abnormally. | As an exception is detected, it is thrown and caught by the "throw" and "catch" keywords correspondingly. |
Types | Errors are classified as unchecked type. | Exceptions are classified as checked or unchecked type. |
Package | In Java, errors are defined "java.lang.Error" package. | In Java, an exceptions are defined in"java.lang.Exception". |
Example | OutOfMemory, StackOverFlow. | Checked Exceptions: NoSuchMethod, ClassNotFound.Unchecked Exceptions: NullPointer, IndexOutOfBounds. |
An exception is first thrown from the top of the stack and if it is not caught, it drops down the call stack to the previous method, If not caught there, the exception again drops down to the previous method, and so on until they are caught or until they reach the very bottom of the call stack. This is called exception propagation.
Example:
/**
* Exception Propagation
*/
class TestExceptionPropagation {
void method1() {
int data = 10 / 0; // generates an exception
System.out.println(data);
}
void method2() {
method1(); // doesn't catch the exception
}
void method3() { // method3 catches the exception
try {
method2();
} catch (Exception e) {
System.out.println("Exception is caught");
}
}
public static void main(String args[]) {
TestExceptionPropagation obj = new TestExceptionPropagation();
obj.method3();
}
}
Some of the common main thread exception are as follows:
-
Exception in thread main java.lang.UnsupportedClassVersionError: This exception comes when your java class is compiled from another JDK version and you are trying to run it from another java version.
-
Exception in thread main java.lang.NoClassDefFoundError: There are two variants of this exception. The first one is where you provide the class full name with .class extension. The second scenario is when Class is not found.
-
Exception in thread main java.lang.NoSuchMethodError: main: This exception comes when you are trying to run a class that doesn't have main method.
-
Exception in thread "main" java.lang.ArithmeticException: Whenever any exception is thrown from main method, it prints the exception is console. The first part explains that exception is thrown from main method, second part prints the exception class name and then after a colon, it prints the exception message.
Throw keyword is used in the method body to throw an exception, while throws is used in method signature to declare the exceptions that can occur in the statements present in the method.
Example:
/**
* Throw in Java
*/
public class ThrowExample {
void checkAge(int age) {
if (age < 18)
throw new ArithmeticException("Not Eligible for voting");
else
System.out.println("Eligible for voting");
}
public static void main(String args[]) {
ThrowExample obj = new ThrowExample();
obj.checkAge(13);
System.out.println("End Of Program");
}
}
Output
Exception in thread "main" java.lang.ArithmeticException:
Not Eligible for voting
at Example1.checkAge(Example1.java:4)
at Example1.main(Example1.java:10)
Example:
/**
* Throws in Java
*/
public class ThrowsExample {
int division(int a, int b) throws ArithmeticException {
int t = a / b;
return t;
}
public static void main(String args[]) {
ThrowsExample obj = new ThrowsExample();
try {
System.out.println(obj.division(15, 0));
} catch (ArithmeticException e) {
System.out.println("You shouldn't divide number by zero");
}
}
}
Output
You shouldn\'t divide number by zero
1. Serial Garbage Collector:
Serial garbage collector works by holding all the application threads. It is designed for the single-threaded environments. It uses just a single thread for garbage collection. The way it works by freezing all the application threads while doing garbage collection may not be suitable for a server environment. It is best suited for simple command-line programs.
Turn on the -XX:+UseSerialGC
JVM argument to use the serial garbage collector.
2. Parallel Garbage Collector:
Parallel garbage collector is also called as throughput collector. It is the default garbage collector of the JVM. Unlike serial garbage collector, this uses multiple threads for garbage collection. Similar to serial garbage collector this also freezes all the application threads while performing garbage collection.
1. Weak References:
Weak Reference Objects are not the default type/class of Reference Object and they should be explicitly specified while using them.
/**
* Weak Reference
*/
import java.lang.ref.WeakReference;
class MainClass {
public void message() {
System.out.println("Weak References Example");
}
}
public class Example {
public static void main(String[] args) {
// Strong Reference
MainClass g = new MainClass();
g.message();
// Creating Weak Reference to MainClass-type object to which 'g'
// is also pointing.
WeakReference<MainClass> weakref = new WeakReference<MainClass>(g);
g = null;
g = weakref.get();
g.message();
}
}
2. Soft References:
In Soft reference, even if the object is free for garbage collection then also its not garbage collected, until JVM is in need of memory badly.The objects gets cleared from the memory when JVM runs out of memory.To create such references java.lang.ref.SoftReference class is used.
/**
* Soft Reference
*/
import java.lang.ref.SoftReference;
class MainClass {
public void message() {
System.out.println("Soft References Example");
}
}
public class Example {
public static void main(String[] args) {
// Strong Reference
MainClass g = new MainClass();
g.message();
// Creating Soft Reference to MainClass-type object to which 'g'
// is also pointing.
SoftReference<MainClass> softref = new SoftReference<MainClass>(g);
g = null;
g = softref.get();
g.message();
}
}
If a primitive type or a string is defined as a constant and the value is known at compile time, the compiler replaces the constant name everywhere in the code with its value. This is called a compile-time constant.
Compile time constant must be:
- Declared final
- Primitive or String
- Initialized within declaration
- Initialized with constant expression
They are replaced with actual values at compile time because compiler know their value up-front and also knows that it cannot be changed during run-time.
private final int x = 10;
Bootstrap ClassLoader is repsonsible for loading standard JDK classs files from rt.jar and it is parent of all class loaders in java. There are three types of built-in ClassLoader in Java:
1. Bootstrap Class Loader: It loads JDK internal classes, typically loads rt.jar and other core classes for example java.lang.* package classes
2. Extensions Class Loader: It loads classes from the JDK extensions directory, usually $JAVA_HOME/lib/ext directory.
3. System Class Loader: It loads classes from the current classpath that can be set while invoking a program using -cp or -classpath command line options.
/**
* ClassLoader
*/
import java.util.logging.Level;
import java.util.logging.Logger;
public class ClassLoaderTest {
public static void main(String args[]) {
try {
// printing ClassLoader of this class
System.out.println("ClassLoader : " + ClassLoaderTest.class.getClassLoader());
// trying to explicitly load this class again using Extension class loader
Class.forName("Explicitly load class", true, ClassLoaderTest.class.getClassLoader().getParent());
} catch (ClassNotFoundException ex) {
Logger.getLogger(ClassLoaderTest.class.getName()).log(Level.SEVERE, null, ex);
}
}
}
The string is Immutable in Java because String objects are cached in String pool. Since cached String literals are shared between multiple clients there is always a risk, where one client's action would affect all another client.
Since string is immutable it can safely share between many threads and avoid any synchronization issues in java.
String Pool in java is a pool of Strings stored in Java Heap Memory. String pool helps in saving a lot of space for Java Runtime although it takes more time to create the String.
When we use double quotes to create a String, it first looks for String with the same value in the String pool, if found it just returns the reference else it creates a new String in the pool and then returns the reference. However using new operator, we force String class to create a new String object in heap space.
/**
* String Pool
*/
public class StringPool {
public static void main(String[] args) {
String s1 = "Java";
String s2 = "Java";
String s3 = new String("Java");
System.out.println("s1 == s2 :" + (s1 == s2)); // true
System.out.println("s1 == s3 :" + (s1 == s3)); // false
}
}
Garbage collection works on Mark and Sweep algorithm. In Mark phase it detects all the unreachable objects and Sweep phase it reclaim the heap space used by the garbage objects and make the space available again to the program.
There are methods like System.gc()
and Runtime.gc()
which is used to send request of Garbage collection to JVM but it's not guaranteed that garbage collection will happen. If there is no memory space for creating a new object in Heap Java Virtual Machine throws OutOfMemoryError
or java.lang.OutOfMemoryError
heap space
An interface with no methods is known as marker or tagged interface. It provides some useful information to JVM/compiler so that JVM/compiler performs some special operations on it. It is used for better readability of code. For example Serializable, Clonnable etc.
Syntax:
public interface Interface_Name {
}
Example:
/**
* Maker Interface
*/
interface Marker {
}
class MakerExample implements Marker {
// do some task
}
class Main {
public static void main(String[] args) {
MakerExample obj = new MakerExample();
if (obj instanceOf Marker) {
// do some task
}
}
}
Serialization is a mechanism of converting the state of an object into a byte stream. Deserialization is the reverse process where the byte stream is used to recreate the actual Java object in memory. This mechanism is used to persist the object.
Example:
/**
* Serialization and Deserialization
*/
import java.io.*;
class Employee implements Serializable {
private static final long serialversionUID = 129348938L;
transient int a;
static int b;
String name;
int age;
// Default constructor
public Employee(String name, int age, int a, int b) {
this.name = name;
this.age = age;
this.a = a;
this.b = b;
}
}
public class SerialExample {
public static void printdata(Employee object1) {
System.out.println("name = " + object1.name);
System.out.println("age = " + object1.age);
System.out.println("a = " + object1.a);
System.out.println("b = " + object1.b);
}
public static void main(String[] args) {
Employee object = new Employee("ab", 20, 2, 1000);
String filename = "file.txt";
// Serialization
try {
// Saving of object in a file
FileOutputStream file = new FileOutputStream(filename);
ObjectOutputStream out = new ObjectOutputStream(file);
// Method for serialization of object
out.writeObject(object);
out.close();
file.close();
System.out.println("Object has been serialized\n"
+ "Data before Deserialization.");
printdata(object);
// value of static variable changed
object.b = 2000;
} catch (IOException ex) {
System.out.println("IOException is caught");
}
object = null;
// Deserialization
try {
// Reading the object from a file
FileInputStream file = new FileInputStream(filename);
ObjectInputStream in = new ObjectInputStream(file);
// Method for deserialization of object
object = (Employee) in.readObject();
in.close();
file.close();
System.out.println("Object has been deserialized\n"
+ "Data after Deserialization.");
printdata(object);
System.out.println("z = " + object1.z);
} catch (IOException ex) {
System.out.println("IOException is caught");
} catch (ClassNotFoundException ex) {
System.out.println("ClassNotFoundException is caught");
}
}
}
The singly linked list is a linear data structure in which each element of the list contains a pointer which points to the next element in the list. Each element in the singly linked list is called a node. Each node has two components: data and a pointer next which points to the next node in the list.
Example:
public class SinglyLinkedList {
// Represent a node of the singly linked list
class Node{
int data;
Node next;
public Node(int data) {
this.data = data;
this.next = null;
}
}
// Represent the head and tail of the singly linked list
public Node head = null;
public Node tail = null;
// addNode() will add a new node to the list
public void addNode(int data) {
// Create a new node
Node newNode = new Node(data);
// Checks if the list is empty
if(head == null) {
// If list is empty, both head and tail will point to new node
head = newNode;
tail = newNode;
}
else {
// newNode will be added after tail such that tail's next will point to newNode
tail.next = newNode;
// newNode will become new tail of the list
tail = newNode;
}
}
// display() will display all the nodes present in the list
public void display() {
// Node current will point to head
Node current = head;
if(head == null) {
System.out.println("List is empty");
return;
}
System.out.println("Nodes of singly linked list: ");
while(current != null) {
// Prints each node by incrementing pointer
System.out.print(current.data + " ");
current = current.next;
}
System.out.println();
}
public static void main(String[] args) {
SinglyLinkedList sList = new SinglyLinkedList();
// Add nodes to the list
sList.addNode(10);
sList.addNode(20);
sList.addNode(30);
sList.addNode(40);
// Displays the nodes present in the list
sList.display();
}
}
Output:
Nodes of singly linked list:
10 20 30 40
If a method declares to throw a given exception, the overriding method in a subclass can only declare to throw that exception or its subclass. This is because of polymorphism.
Example:
class A {
public void message() throws IOException {..}
}
class B extends A {
@Override
public void message() throws SocketException {..} // allowed
@Override
public void message() throws SQLException {..} // NOT allowed
public static void main(String args[]) {
A a = new B();
try {
a.message();
} catch (IOException ex) {
// forced to catch this by the compiler
}
}
}
1. Checked Exception:
- These are the classes that extend Throwable except RuntimeException and Error.
- They are also known as compile time exceptions because they are checked at compile time, meaning the compiler forces us to either handle them with try/catch or indicate in the function signature that it throws them and forcing us to deal with them in the caller.
- They are programmatically recoverable problems which are caused by unexpected conditions outside the control of the code (e.g. database down, file I/O error, wrong input, etc).
Example: IOException, SQLException etc.
import java.io.*;
class Main {
public static void main(String[] args) {
FileReader file = new FileReader("C:\\assets\\file.txt");
BufferedReader fileInput = new BufferedReader(file);
for (int counter = 0; counter < 3; counter++)
System.out.println(fileInput.readLine());
fileInput.close();
}
}
output:
Exception in thread "main" java.lang.RuntimeException: Uncompilable source code -
unreported exception java.io.FileNotFoundException; must be caught or declared to be
thrown
at Main.main(Main.java:5)
After adding IOException
import java.io.*;
class Main {
public static void main(String[] args) throws IOException {
FileReader file = new FileReader("C:\\assets\\file.txt");
BufferedReader fileInput = new BufferedReader(file);
for (int counter = 0; counter < 3; counter++)
System.out.println(fileInput.readLine());
fileInput.close();
}
}
output:
Output: First three lines of file “C:\assets\file.txt”
2. Unchecked Exception:
- The classes that extend RuntimeException are known as unchecked exceptions.
- Unchecked exceptions are not checked at compile-time, but rather at runtime, hence the name.
- They are also programmatically recoverable problems but unlike checked exception they are caused by faults in code flow or configuration.
Example: ArithmeticException, NullPointerException, ArrayIndexOutOfBoundsException etc.
class Main {
public static void main(String args[]) {
int x = 0;
int y = 10;
int z = y/x;
}
}
Output:
Exception in thread "main" java.lang.ArithmeticException: / by zero
at Main.main(Main.java:5)
Java Result: 1
3. Error:
Error refers to an irrecoverable situation that is not being handled by a try/catch. Example: OutOfMemoryError, VirtualMachineError, AssertionError etc.
ClassNotFoundException
and NoClassDefFoundError
occur when a particular class is not found at runtime. However, they occur at different scenarios.
ClassNotFoundException
is an exception that occurs when you try to load a class at run time using Class.forName()
or loadClass()
methods and mentioned classes are not found in the classpath.
NoClassDefFoundError
is an error that occurs when a particular class is present at compile time, but was missing at run time.
A weakly referenced object is cleared by the Garbage Collector when it's weakly reachable.
Weak reachability means that an object has neither strong nor soft references pointing to it. The object can be reached only by traversing a weak reference. To create such references java.lang.ref.WeakReference
class is used.
/**
* Weak reference
*/
import java.lang.ref.WeakReference;
class WeakReferenceExample {
public void message() {
System.out.println("Weak Reference Example!");
}
}
public class MainClass {
public static void main(String[] args) {
// Strong Reference
WeakReferenceExample obj = new WeakReferenceExample();
obj.message();
// Creating Weak Reference to WeakReferenceExample-type object to which 'obj'
// is also pointing.
WeakReference<WeakReferenceExample> weakref = new WeakReference<WeakReferenceExample>(obj);
obj = null; // is available for garbage collection.
obj = weakref.get();
obj.message();
}
}
Output
Weak Reference Example!
Weak Reference Example!
Polymorphism
in Java is a concept by which we can perform a single action in different ways.
There are two types of polymorphism in java:
- Static Polymorphism also known as compile time polymorphism
- Dynamic Polymorphism also known as runtime polymorphism
Example: Static Polymorphism
class SimpleCalculator {
int add(int a, int b) {
return a + b;
}
int add(int a, int b, int c) {
return a + b + c;
}
}
public class MainClass
{
public static void main(String args[]) {
SimpleCalculator obj = new SimpleCalculator();
System.out.println(obj.add(10, 20));
System.out.println(obj.add(10, 20, 30));
}
}
Output
30
60
Example: Runtime polymorphism
class ABC {
public void myMethod() {
System.out.println("Overridden Method");
}
}
public class XYZ extends ABC {
public void myMethod() {
System.out.println("Overriding Method");
}
public static void main(String args[]) {
ABC obj = new XYZ();
obj.myMethod();
}
}
Output
Overriding Method
Q. If I do not have Explicit constructor in parent class and having in child class, while calling the child constructor jvm automatically calls Implicit Constructor of parent class?
If the subclass constructor does not specify which superclass constructor to invoke then the compiler will automatically call the accessible no-args constructor in the superclass.
JDBC Driver is a software component that enables java application to interact with the database.
There are 4 types of JDBC drivers:
- JDBC-ODBC bridge driver: The JDBC-ODBC bridge driver uses ODBC driver to connect to the database. The JDBC-ODBC bridge driver converts JDBC method calls into the ODBC function calls. This is now discouraged because of thin driver.
- Native-API driver: The Native API driver uses the client-side libraries of the database. The driver converts JDBC method calls into native calls of the database API. It is not written entirely in java.
- Network Protocol driver: The Network Protocol driver uses middleware (application server) that converts JDBC calls directly or indirectly into the vendor-specific database protocol. It is fully written in java.
- Thin driver: The thin driver converts JDBC calls directly into the vendor-specific database protocol. That is why it is known as thin driver. It is fully written in Java language.
Encapsulation in Java is a mechanism of wrapping the data (variables) and code acting on the data (methods) together as a single unit. In encapsulation, the variables of a class will be hidden from other classes, and can be accessed only through the methods of their current class. Therefore, it is also known as data hiding
.
To achieve encapsulation in Java −
- Declare the variables of a class as private.
- Provide public setter and getter methods to modify and view the variables values.
Example:
public class EncapClass {
private String name;
public String getName() {
return name;
}
public void setName(String newName) {
name = newName;
}
}
public class MainClass {
public static void main(String args[]) {
EncapClass obj = new EncapClass();
obj.setName("Pradeep Kumar");
System.out.print("Name : " + obj.getName());
}
}
Generics
allows type (Integer, String, … etc and user defined types) to be a parameter to methods, classes and interfaces. For example, classes like HashSet, ArrayList, HashMap, etc use generics very well.
Advantages
- Type-safety: We can hold only a single type of objects in generics. It doesn't allow to store other objects.
- Type Casting: There is no need to typecast the object.
- Compile-Time Checking: It is checked at compile time so problem will not occur at runtime.
Example:
/**
* A Simple Java program to show multiple
* type parameters in Java Generics
*
* We use < > to specify Parameter type
*
**/
class GenericClass<T, U> {
T obj1; // An object of type T
U obj2; // An object of type U
// constructor
GenericClass(T obj1, U obj2) {
this.obj1 = obj1;
this.obj2 = obj2;
}
// To print objects of T and U
public void print() {
System.out.println(obj1);
System.out.println(obj2);
}
}
// Driver class to test above
class MainClass {
public static void main (String[] args) {
GenericClass <String, Integer> obj =
new GenericClass<String, Integer>("Generic Class Example !", 100);
obj.print();
}
}
Output:
Generic Class Example !
100
String is immutable
, if you try to alter their values, another object gets created, whereas StringBuffer
and StringBuilder
are mutable so they can change their values.
The difference between StringBuffer
and StringBuilder
is that StringBuffer
is thread-safe. So when the application needs to be run only in a single thread then it is better to use StringBuilder
. StringBuilder
is more efficient than StringBuffer.
Situations:
- If your string is not going to change use a String class because a
String
object is immutable. - If your string can change (example: lots of logic and operations in the construction of the string) and will only be accessed from a single thread, using a
StringBuilder
is good enough. - If your string can change, and will be accessed from multiple threads, use a
StringBuffer
becauseStringBuffer
is synchronous so you have thread-safety.
Example:
class StringExample {
// Concatenates to String
public static void concat1(String s1) {
s1 = s1 + "World";
}
// Concatenates to StringBuilder
public static void concat2(StringBuilder s2) {
s2.append("World");
}
// Concatenates to StringBuffer
public static void concat3(StringBuffer s3) {
s3.append("World");
}
public static void main(String[] args) {
String s1 = "Hello";
concat1(s1); // s1 is not changed
System.out.println("String: " + s1);
StringBuilder s2 = new StringBuilder("Hello");
concat2(s2); // s2 is changed
System.out.println("StringBuilder: " + s2);
StringBuffer s3 = new StringBuffer("Hello");
concat3(s3); // s3 is changed
System.out.println("StringBuffer: " + s3);
}
}
Output
String: Hello
StringBuilder: World
StringBuffer: World
Different ways to create an object in Java
- Using new Keyword
class ObjectCreationExample{
String Owner;
}
public class MainClass {
public static void main(String[] args) {
// Here we are creating Object of JBT using new keyword
ObjectCreationExample obj = new ObjectCreationExample();
}
}
- Using New Instance (Reflection)
class CreateObjectClass {
static int j = 10;
CreateObjectClass() {
i = j++;
}
int i;
@Override
public String toString() {
return "Value of i :" + i;
}
}
class MainClass {
public static void main(String[] args) {
try {
Class cls = Class.forName("CreateObjectClass");
CreateObjectClass obj = (CreateObjectClass) cls.newInstance();
CreateObjectClass obj1 = (CreateObjectClass) cls.newInstance();
System.out.println(obj);
System.out.println(obj1);
} catch (ClassNotFoundException e) {
e.printStackTrace();
} catch (InstantiationException e) {
e.printStackTrace();
} catch (IllegalAccessException e) {
e.printStackTrace();
}
}
}
- Using Clone
class CreateObjectWithClone implements Cloneable {
@Override
protected Object clone() throws CloneNotSupportedException {
return super.clone();
}
int i;
static int j = 10;
CreateObjectWithClone() {
i = j++;
}
@Override
public String toString() {
return "Value of i :" + i;
}
}
class MainClass {
public static void main(String[] args) {
CreateObjectWithClone obj1 = new CreateObjectWithClone();
System.out.println(obj1);
try {
CreateObjectWithClone obj2 = (CreateObjectWithClone) obj1.clone();
System.out.println(obj2);
} catch (CloneNotSupportedException e) {
e.printStackTrace();
}
}
}
- Using ClassLoader
class CreateObjectWithClassLoader {
static int j = 10;
CreateObjectWithClassLoader() {
i = j++;
}
int i;
@Override
public String toString() {
return "Value of i :" + i;
}
}
public class MainClass {
public static void main(String[] args) {
CreateObjectWithClassLoader obj = null;
try {
obj = (CreateObjectWithClassLoader) new MainClass().getClass()
.getClassLoader().loadClass("CreateObjectWithClassLoader").newInstance();
// Fully qualified classname should be used.
} catch (InstantiationException e) {
e.printStackTrace();
} catch (IllegalAccessException e) {
e.printStackTrace();
} catch (ClassNotFoundException e) {
e.printStackTrace();
}
System.out.println(obj);
}
}
The Object class is the parent class of all the classes in java by default.
Method | Description |
---|---|
public final Class getClass() | returns the Class class object of this object. The Class class can further be used to get the metadata of this class. |
public int hashCode() | returns the hashcode number for this object. |
public boolean equals(Object obj) | compares the given object to this object. |
protected Object clone() throws CloneNotSupportedException | creates and returns the exact copy (clone) of this object. |
public String toString() | returns the string representation of this object. |
public final void notify() | wakes up single thread, waiting on this object\'s monitor. |
public final void notifyAll() | wakes up all the threads, waiting on this object\'s monitor. |
public final void wait(long timeout)throws InterruptedException | causes the current thread to wait for the specified milliseconds, until another thread notifies (invokes notify() or notifyAll() method). |
public final void wait(long timeout,int nanos)throws InterruptedException | causes the current thread to wait for the specified milliseconds and nanoseconds, until another thread notifies (invokes notify() or notifyAll() method). |
public final void wait()throws InterruptedException | causes the current thread to wait, until another thread notifies (invokes notify() or notifyAll() method). |
protected void finalize()throws Throwable | is invoked by the garbage collector before object is being garbage collected. |
ToDo