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Core JavaAbstraction:
Abstraction will Show functionality hide complexity. We can
achieve Abstraction in two ways first is by interface and second is by
Abstract class.
For real life example " All electronic device " viz., Mobile, Pen.
Eg:
Encapsulation:
Encapsulation is the mechanism that binds together code and
data it manipulates and keeps both safe from outside interference and
misuse.
Encapsulation refers to keeping all the related members (variables
and methods) together in an object. Specifying members as private
can hide the variables and methods. Objects should hide their inner
workings from the outside view. Good encapsulation improves code
modularity by preventing objects interacting with each other in an
unexpected way, which in turn makes future development and
refactoring efforts easy.
Encapsulation is the process of binding together the method and
data variable as a single entity. It keeps both the data and
functionality code safe from outside world .It hide the data within
class and make it available only through the method.
Benefits: The main benefit of encapsulation is the ability to modify
our implemented code without breaking the code of others who use
our code. With this feature Encapsulation gives maintainability,
flexibility and extensibility to our code.
The fields of a class can be made read-only or write-only.
A class can have total control over what is stored in its fields.
The users of a class do not know how the class stores its data. A
class can change the data type of a field, and users of the class
do not need to change any of their code.
For real life example: A Person's mind is encapsulated, cannot be
seen, one can try to read it by interacting with him. Capsule
Medicine or Gems Packet
Example code:-
class check{
private int amount=0;
public int getAmount() {
return amount;
}
public void setAmount(int amt) {
amount=amt; }
}
public class Mainclass {
public static void main(String[]arg) {
int amt = 0;
check obj = new check();
obj.setAmount(200);
amt = obj.getAmount();
System.out.println("your current amount is"+ amt );
}
}
Inheritance:
Inheritance is the process by which one object acquires the
properties of another object. A very important fact to remember is
that Java only supports only single inheritance. This means that a
class cannot extend more than one class. However a class can
implement one or more interfaces. This has made Java get rid of the
impossibility of multiple inheritance
IS-A Relationship: This object is a type of that object.
Extends: With use of the extends keyword the subclasses will be able
to inherit all the properties of the superclass except for the private
properties of the superclass.
Example code:
public class Animal{ }
public class Mammal extends Animal{}
public class Reptile extends Animal{}
public class Dog extends Mammal{}
Now if we consider the IS-A relationship we can say:
Mammal IS-A Animal
Reptile IS-A Animal
Dog IS-A Mammal
Hence : Dog IS-A Animal as well.
Implements:The implements keyword is used by classes by inherit
from interfaces. Interfaces can never be extended.
Example code:
public interface Animal {}
public class Mammal implements Animal{}
public class Dog extends Mammal{}
HAS-A Relationship: This determines whether a certain class
HAS-A certain thing. This relationship helps to reduce duplication of
code as well as bugs.
public class Vehicle{}
public class Speed{}
public class Van extends Vehicle{
private Speed sp;
}
This shows that class Van HAS-A Speed. By having a separate class
for Speed we do not have to put the entire code that belongs to speed
inside the Van class., which makes it possible to reuse the Speed class
in multiple applications.
Real time example: Parent and Child where child acquires all
the properties of a parent.
Benefits: With the use of inheritance the information is made
manageable in a hierarchical order.
No multiple inheritance in java?
Yes , there is no direct multiple inheritance in java as it may duplicate
the methods in the child classes. But there is a possibility of having
the multiple inheritance in java using the interfaces which will be of
major importance in any of the Projects.
Polymorphism:
Polymorphism is the feature that allows one interface to be used for
general class actions. When the JVM invokes a class instance method,
it selects the method to invoke based on the type of the object
reference, which is always known at run-time. On the other hand,
when the JVM invokes a static method, it selects the method to invoke
based on the actual class of the object, which may only be known at
compile time.
Need of Polymorphism
Polymorphism is the association between a generalized
reference and a more specific object.
The ability of a reference variable to change behavior according
to what object instance it is holding.
Polymorphism in simple terms means one name many forms.
Polymorphism enables one entity to be used as a general
category for different types of actions. The specific action is
determined by the exact nature of the situation.
Polymorphism exists in three distinct forms in Java:
• Method overloading
• Method overriding through inheritance
• Method overriding through the Java interface.
Difference between method overriding and
overloading?
Overriding is a method with the same name and arguments as in a
parent, whereas overloading is the same method name but different
arguments.
Eight primitive Java types?
Ans: The eight primitive types are byte, char, short, int, long, float,
double, and boolean.
Restrictions are placed on method overriding?
• Overridden methods must have the same name, argument list, and
return type.
• The overriding method may not limit the access of the method it
overrides.
• The overriding method may not throw any exceptions that may not
be thrownby the overridden method.
Restrictions are placed on method overloading?
Two methods may not have the same name and argument list but
different return types.
Casting?
Ans:There are two types of casting, casting between primitive
numeric types and casting between object references. Casting
between numeric types is used to convert larger values, such as
double values, to smaller values, such as byte values. Casting between
object references is used to refer to an object by a compatible class,
interface, or array type reference
Java package and how is it used?
Ans: A Java package is a naming context for classes and interfaces. A
package is used to create a separate name space for groups of classes
and interfaces. Packages are also used to organize related classes and
interfaces into a single API unit and to control accessibility to these
classes and interfaces.
this and super used?
this is used to refer to the current object instance. super is used to
refer to the variables and methods of the super class of the current
object instance
What is a stream and what are the types of Streams
and classes of the Streams?-
A Stream is an abstraction that either produces or consumes
information. There are two types of Streams and they are:
Byte Streams: Provide a convenient means for handling input and
output of bytes. Character Streams: Provide a convenient means for
handling input & output of characters. Byte Streams classes: Are
defined by using two abstract classes, namely InputStream and
OutputStream.
Character Streams classes: Are defined by using two abstract
classes, namely Reader and Writer
Can a method be overloaded based on different return
type but same argument type ?
No, because the methods can be called without using their return type
in which case there is ambiquity for the compiler.
Association?
Association is a relationship between two classes. In this relationship
the object of one instance perform an action on behalf of the other
class. The typical behaviour can be invoking the method of other class
and using the member of the other class.
Aggregation?
Aggregation has a relationship between two classes. In this
relationship the object of one class is a member of the other class.
Aggregation always insists for a direction.
What are pass by reference and pass by value?
Pass By Reference means the passing the address itself rather than
passing the value.
Passby Value means passing a copy of the value to be passed.
Java supports only pass by value. The arguments passed as a
parameter to a method is mainly primitive data types or objects. For
the data type the actual value is passed.
Java passes the references by value just like any other parameter.
This means the references passed to the method are actually copies of
the original references. Java copies and passes the reference by value,
not the object. Thus, method manipulation will alter the objects, since
the references point to the original objects. Consider the example:
public void tricky(Point arg1, Point arg2)
{
arg1.x = 100;
arg1.y = 100;
Point temp = arg1;
arg1 = arg2;
arg2 = temp;
}
public static void main(String [] args)
{
Point pnt1 = new Point(0,0);
Point pnt2 = new Point(0,0);
System.out.println("X: " + pnt1.x + " Y: " +pnt1.y);
System.out.println("X: " + pnt2.x + " Y: " +pnt2.y);
System.out.println(" ");
tricky(pnt1,pnt2);
System.out.println("X: " + pnt1.x + " Y:" + pnt1.y);
System.out.println("X: " + pnt2.x + " Y: " +pnt2.y);
}
OutPut:
X: 0 Y: 0
X: 0 Y: 0
X: 100 Y: 100
X: 0 Y: 0
The method successfully alters the value of pnt1, even though it is
passed by value; however, a swap of pnt1 and pnt2 fails! This is the
major source of confusion. In the main() method, pnt1 and pnt2 are
nothing more than object references. When you pass pnt1 and pnt2 to
the tricky() method, Java passes the references by value just like any
other parameter. This means the references passed to the method are
actually copies of the original references.
Locale class?
The Locale class is used to tailor program output to the conventions of
a particular geographic, political, or cultural region.
Final():
Final () method is used for constant declaration. A final variable act
as constant, a final class is immutable A final method can't be
overridden when its class is inherited. You can't change value of a
final variable (is a constant).
A final class can't be extended i.e., final class may not be sub
classed.
Finally():
Handles exception.
The finally block is optional and provides a mechanism to clean up
regardless of what happens within the try block (except
System.exit(0) call).
Use the finally block to close files or to release other system
resources like database connections, statements etc.
Finalize() –
method helps in garbage collection.
A method that is invoked before an object is discarded by the
garbage collector, allowing it to clean up its state. Should not be used
to release non-memory resources like file handles, sockets, database
connections etc because
Java has only a finite number of these resources and you do not
know when the garbage collection is going to kick in to release these
non-memory resources through the finalize() method.
Difference between declaring a variable and defining a
variable?
In declaration we just mention the type of the variable and it's name.
We do not initialize it.
But defining means declaration + initialization.
e.g. String s; is just a declaration while String s = new String
("abcd"); Or String s = "abcd"; are both definitions.
Differents Ways To Create An Object Of A Class
In Java:
There are four different ways to create objects in java:
1) Using new keyword This is the most common way to create an
object in java. Almost 99% of objects are created in this way
MyObject object = new MyObject();
2) Using Class.forName() If we know the name of the class & if it
has a public default constructor we can create an object in this way. It
is also known as reflection.
MyObject object =
(MyObject)Class.forName("subin.rnd.MyObject"). newInstance();
3) Using clone() The clone() can be used to create a copy of an
existing object.
MyObject anotherObject = new MyObject();
MyObject object = anotherObject.clone();
4)Using object deserialization Object deserialization is nothing but
creating an object from its serialized form.
ObjectInputStream inStream = new
ObjectInputStream(anInputStream );
MyObject object = (MyObject) inStream.readObject();
5) Using reflection in another way.
this.getClass().getClassLoader().loadClass(“com.amar.myobject”
).newInstance();
J2SE 1.4 (february 6, 2002) merlin
- assert keyword
- Regular expressions
- Exception chaining (allows an exception to encapsulate original
lower-level exception)
- Internet protocol version 6 (IPV6) support
- Non-blocking nio (new input/output)
- Logging API
- Image i/o api for reading and writing images in formats like jpeg and
png
- Integrated XML parser and XSLT processor (JAXP)
- Integrated security and cryptography extensions (JCE, JSSE, JAAS)
- Java web start
J2SE 5.0 (september 30, 2004) tiger [originally numbered 1.5]
Generics
Allows programmers to specify the types allowed for Collections
Allows the compiler to enforce the type specifications
//Before
List stringList
//In JDK 1.5
List<String> stringList;
Varargs:
the last parameter of a method can now be declared using a type
name followed by three dots (e.g. Void drawtext(string... Lines)). In
the calling code any number of parameters of that type can be used
and they are then placed in an array to be passed to the method, or
alternatively the calling code can pass an array of that type.
Allow a variable number of arguments for methods like printf() or
Method.invoke()
Internally parameters are an array of Object
Compiler constructs array for the call
void printf(String format, Object?args);
?
printf(?{0} {1} ?, ?Hello?, ?World?);
printf(?PI = {0}?, 3.14159);
Metadata: also called annotations; allows language constructs such
as classes and methods to be tagged with additional data, which can
then be processed by metadata-aware utilities.
Autoboxing/unboxing: automatic conversions between primitive
types (such as int, boolean) and primitive wrapper classes (such as
integer).
Enumerations: the enum keyword creates a typesafe, ordered list of
values (such as day.monday, day.tuesday, etc.). Previously this could
only be achieved by non-typesafe constant integers or manually
constructed classes (typesafe enum pattern).
- Swing: new skinnable look and feel, called synth.
Enhanced for each loop: it internally extends IEnumerable interface
and for-each loop is used to access each successive value in a
collection of values.
Here is a loop written as both a for-each loop and a basic for loop.
double[] ar = {1.2, 3.0, 0.8};
int sum = 0;
for (double d : ar) { // d gets successively each value in ar.
sum += d;
}
basic for. It requires an extra iteration variable.
double[] ar = {1.2, 3.0, 0.8};
int sum = 0;
for (int i = 0; i < ar.length; i++) { // i indexes each element
successively.
sum += ar[i];
}
//Before
for(Iterator i = line.iterator();i.hasNext(); )
{
String word = (String)i.next();
?
}
//In JDK 1.5
for(String word: line)
{
?
}
For each in JSP: <c:forEach var="product"
items="$(testattribute}">
<tr><td>${product}</td></tr>
</c:forEach>
- Automatic stub generation for rmi objects.
- Static imports concurrency utilities in package
java.util.concurrent.
- Scanner class for parsing data from various input streams and
buffers.
- StringBuilder class (in java.lang package)
- Annotations
Abstract class and methods
What is an Abstract Class and what is its
purpose?
A Class which doesn’t provide complete implementation is defined as
an abstract class. Abstract classes enforce abstraction.
Can an abstract class be declared final?
Not possible. An abstract class without being inherited is of no use
and hence will result in compile time error.
What is use of an abstract variable?
Variables can’t be declared as abstract. Only classes and methods can
be declared as abstract.
Can you create an object of an abstract class?
Not possible. Abstract classes can’t be instantiated.
Can an abstract class be defined without any
abstract methods?
Yes it’s possible. This is basically to avoid instance creation of the
class.
What is an abstract method?
An abstract method is a method whose implementation is deferred to
a subclass.
What does it mean that a method or class is
abstract?
An abstract class cannot be instantiated. Abstract methods may only
be included in abstract classes. However, an abstract class is not
required to have any abstract methods, though most of them do. Each
subclass of an abstract class must override the abstract methods of its
super classes or it also should be declared abstract
Interface:
Why do you create interfaces, and when MUST you use
one?
we create interface bcoz ...
1. To implement multiple inheritance in java.
2. To advertise the compiler that class implementing that interface is
ready to deliver the functionality defined by the interface. We use the
interface in cases where the classes need to define the same method
but the way of execution is different for every classes depending on
their need.
e.g.:- If we want to sort between two employee object on the basis of
salary we have to implement the comparable interface and define the
compareTo()such that it sorts on salary.
but if we want to sort two manager object on age basis we again have
to implement the comparable interface and define the compareTo()
method but the code written inside the compareTo() method is now
different from the above one .
Now both implement the same interface and define the same method
but still the way of execution is different .One sort on age another on
salary .implementing comparable interface advertise the compiler that
class implementing this interface will compare data but the basis of
comparison depends upon the code written in compareTo().
Can a method inside a Interface be declared as final?
No not possible. Doing so will result in compilation error. public and
abstract are the only applicable modifiers for method declaration in
an interface.
Can an Interface implement another Interface?
Interfaces doesn’t provide implementation hence a interface cannot
implement another interface.
Can an Interface extend another Interface?
Yes an Interface can inherit another Interface, for that matter an
Interface can extend more than one Interface.
Can a Class extend more than one Class?
Not possible. A Class can extend only one class but can implement any
number of Interfaces.
Why is an Interface be able to extend more than one
Interface but a Class can’t extend more than one
Class?
Basically Java doesn’t allow multiple inheritances, so a Class is
restricted to extend only one class. But an Interface is a pure
abstraction model and doesn’t have inheritance hierarchy like
classes(do remember that the base class of all classes is Object). So
an Interface is allowed to extend more than one Interface.
Can an Interface be final?
Not possible. Doing so so will result in compilation error.
Can a class be defined inside an Interface?
Yes it’s possible.
Can an Interface be defined inside a class?
Yes it’s possible.
Can i declare variables inside Interface? If yes then
how?
Variables inside an Interface is only constants..i mean you can say
something like
public static final int=20. Generally, Constants are used for
readability and convenience.
Eg: e.g.
interface UsefulAction {
public static int ACTION_SUCCESS = 1;
public static int ACTION_FAILURE = 0;
public int doAction();
}
Any class implementing the Useful Action interface must implement
the doAction() method which returns an int value and one could
reasonably expect that value to correspond one of the constants, so
that the calling code can be written thus.
int result = doAction();
if (result == ACTION_SUCCESS) {
// continue processing
} else {
// handle the failure
}
Both yes and no: yes, you can declare interface fields but they will
automatically receive "public", "static" and "final" modifiers so they
will be constants, so no, there will be no variables.
But you surely can declare some Singleton as an Interface static final
field which will held some variables inside of it. That's how you can
obtain static fields of an Interface.
However it is a bad practice and should not be used since Interface
declares how the particular object will be used while mutable field is a
part of implementation. And for partial implementation abstract
classes are preferred
What is a Marker Interface?
An Interface which doesn’t have any declaration inside but still
enforces a mechanism.
An interface which has no methods is called marker interface. If we
implement that interface jvm will provide ability to the object
Eg is Serializable. When a class implements this interface then only
we can serialize the object. i.e we can save in the file. In other words
any class which implements serializable can be serialized which is the
additional feature when compared with an ordianary object
When can an object reference be cast to an interface
reference?
An object reference be cast to an interface reference when the object
implements the referenced interface.
What is fully abstract class?
Ans) An abstract class which has all methods as abstract and all fields
are public static final.
Difference between Abstract and interface:
1) An abstract class can define both abstract and non-abstract
methods, an interface can have only abstract methods.
2) An interface can extend one or more other interfaces. An
interface cannot extend anything but another interface. An
interface cannot implement another interface or class. An
interface must be declared with the keyword interface.
Transient variable?
These variables are not included in the process of serialization and
are not the part of the object’s serialized state.
Does the order in which the value of the transient variables and
the state of the object using the defaultWriteObject() method
are saved during serialization matter?
Yes. As while restoring the object’s state the transient variables and
the serializable variables that are stored must be restored in the same
order in which they were saved.
About Main()
Why is main() method static?
To access the static method the object of the class is not needed. The
method can be access directly with the help of ClassName. So when a
program is started the jvm search for the class with main method and
calls it without creating an object of the class.
What is the return type of the main method?
Main method doesn’t return anything hence declared void.
Why the main method is declared static?
Main method is called by the JVM even before the instantiation of the
class hence it is declared as static.
What is the argument of main method?
Main method accepts an array of String object as argument.
Can a main method be overloaded?
Yes. You can have any number of main methods with different method
signature and implementation in the class.
Can a main method be declared final?
Yes. Any inheriting class will not be able to have it’s own default main
method.
What is a native method?
A native method is a method that is implemented in a language other
than Java.
Why not static public void main?
Actually you can have a static public void main. The java compiler or
the JVM does not complain about the order in which the keywords are
placed for the main method as long as all of them are there.
What happens if you remove public from public static
void main?
Until you run the program nothing happens. You would be able to
happily compile your program, but when you try to execute it, you will
get the below exception. Main Method Not Public
Why public static void main?
public - so that any class can access it static - so that the JVM can
access it without the need to instantiate the class object void -
because it does not return anything main - this is just the...
What is public static void main in java?
The method of an class that can is triggered when starting a Java
application e.g. by running the command: "java MyProgram" Answer
Public is an Access Specifier, static is a keyword which so that the
JVM can access it without the need to instantiate the class object...
Should a main method be compulsorily declared in all
java classes?
No not required. main method should be defined only if the source
class is a java application.
Can you have an inner class inside a method and what
variables can you access?-
Yes, we can have an inner class inside a method and final variables
can be accessed.
What will be the value of transient variable after de-
serialization?
Ans) It’s default value.
E.g. if the transient variable in question is an int, it’s value after
deserialization will be zero.
Explanation –
The transient variable is not saved as the part of the
state of the serailized variable, it’s value after de-
serialization is it’s default value.
public class TestTransientVal implements Serializable{
private static final long serialVersionUID = -22L;
private String name;
transient private int age;
TestTransientVal(int age, String name) {
this.age = age;
this.name = name; }
public static void main(String [] args) {
TestTransientVal c = new TestTransientVal(1,"ONE");
System.out.println("Before serialization: - " + c.name + " "+
c.age);
try {
FileOutputStream fs = new
FileOutputStream("testTransients.ser");
ObjectOutputStream os = new ObjectOutputStream(fs);
os.writeObject(c);
os.close();
} catch (Exception e) { e.printStackTrace(); }
try {
FileInputStream fis = new FileInputStream("testTransients.ser");
ObjectInputStream ois = new ObjectInputStream(fis);
c = (TestTransientVal) ois.readObject();
ois.close();
} catch (Exception e) { e.printStackTrace(); }
System.out.println("After de-serialization:- " + c.name + " "+
c.age);
} }
Result of executing above piece of code –
Before serialization: - Value of non-transient variable ONE Value of
transient variable 1
After de-serialization:- Value of non-transient variable ONE Value of
transient variable 0
About String
Differences between String and StringBuffer in Java
String is immutable while StringBuffer is mutable means you
can modify a StringBuffer object once you created it without creating
any new object. This mutable property makes StringBuffer an ideal
choice for dealing with Strings in Java. You can convert a StringBuffer
into String by its toString() method.
Difference between StringBuilder and StringBuffer in
Java
StringBuffer is very good with mutable String but it has one
disadvantage all its public methods are synchronized which makes it
thread-safe but same time slow. In JDK 5 they provided similar class
called StringBuilder in Java which is a copy of StringBuffer but
without synchronization. Try to use StringBuilder whenever possible it
performs better in most of cases than StringBuffer class. You can also
use "+" for concatenating two string because "+" operation is internal
implemented using either StringBuffer or StringBuilder in Java. If you
see StringBuilder vs StringBuffer you will find that they are exactly
similar and all API methods applicable to StringBuffer are also
applicable to StringBuilder in Java. On the other hand String vs
StringBuffer is completely different and there API is also completely
different, same is true for StringBuilders vs String.
Summary
1) String is immutable while StringBuffer and StringBuilder is
mutable object.
2) StringBuffer is synchronized while StringBuilder is not which
makes StringBuilder faster than StringBuffer.
3) Concatenation operator "+" is internal implemented using either
StringBuffer or StringBuilder.
4) Use String if you require immutability, use Stringbuffer in java if
you need mutable + threadsafety and use StringBuilder in Java if you
require mutable + without thread-safety.
Difference between String and
StringBuffer/StringBuilder?
Well, the most important difference between String and
StringBuffer/StringBuilder in java is that String object is immutable
whereas StringBuffer/StringBuilder objects are mutable.
By immutable, we mean that the value stored in the String object
cannot be changed. Then the next question that comes to our mind is
“If String is immutable then how am I able to change the contents of
the object whenever I wish to?” . Well, to be precise it’s not the same
String object that reflects the changes you do. Internally a new String
object is created to do the changes.
So suppose you declare a String object:
String myString = “Hello”;
Next, you want to append “Guest” to the same String. What do you
do?
myString = myString + ” Guest”;
When you print the contents of myString the output will be “Hello
Guest”. Although we made use of the same object(myString),
internally a new object was created in the process. So, if you were to
do some string operation involving an append or trim or some other
method call to modify your string object, you would really be creating
those many new objects of class String.
Now isn’t that a performance issue?
Yes, it definitely is.
How do you make your string operations efficient?
By using StringBuffer or StringBuilder.
How would that help?
Well, since StringBuffer/StringBuilder objects are mutable, we can
make changes to the value stored in the object. What this effectively
means is that string operations such as append would be more
efficient if performed using StringBuffer/StringBuilder objects than
String objects.
What is difference between stringbuffer and
stringbuilder?
StringBuffer and StringBuilder have the same methods with one
difference and that’s of synchronization. StringBuffer is synchronized(
which means it is thread safe and hence you can use it when you
implement threads for your methods) whereas StringBuilder is not
synchronized( which implies it isn’t thread safe).
So, if you aren’t going to use threading then use the StringBuilder
class as it’ll be more efficient than StringBuffer due to the absence of
synchronization.
Incase you do not know – Here’s how you use StringBuilder
A simple Example to demonstrate that String object is Immutable
Incase you still have any doubts regarding String or StringBuilder
then do leave a comment. I’ll be more than eager to help you out.
The only difference between StringBuffer and StringBuilder is
that StringBuilder is unsynchronized whereas StringBuffer is
synchronized. 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.
Criteria to choose among StringBuffer and StringBuilder
1)If your text can change and will only be accessed from a single
thread, use a StringBuilder because StringBuilder is unsynchronized.
If your text can changes, and will be accessed from multiple threads,
use a StringBuffer because StringBuffer is synchronous
Mutable string means we can append to that string. example
StringBuffer object is mutable string. String is immutable object..
when we declre String="abc"; a string object abc with fixed length is
created. We cant add anything to it .If we do java simply creates a
new object.
How to compare Stringbuffer objects?
Stringbuffer can be converted to string objects and compared using
compare method..
String objects are immutable. Well let me explain taking an
example:Look at the code below along with the comments:String test
= "Java"; // Create a string object "java" and assign a reference 'test '
to it.String test2 = test; //create another reference test2. Now both
the references point to the //same string object i.e. "java"test = test +
"world"; //this statement creates another string object i.e. "java world"
and now the reference test refers to this object and not to "java"
implying that string objects are immutable. The previous object "java"
is then garbage collected if there is no other refrence to it. Right now
test2 points to it, so it isnt garbage collected.System.out.println("test
"+test);//Having understood the above, u can make out the output of
this line. it will be "java world"System.out.println("test2 "+test2);//out
put of this will be "java".Hope this makes it clear.
I have one string like "Happy Birthday to you". But i
want to print it like "you to Birthday Happy". Pls tell
me the program on java?
import java.util.*; class ReverseString1 {
public static void main(String[]arg) {
String input ="Happy Birthday To You";
Stack stack = new Stack();
StringTokenizer strTok = new StringTokenizer(input);
while(strTok.hasMoreTokens()){
stack.push(strTok.nextElement());
}
StringBuffer revStr = new StringBuffer();
while(!stack.empty()){
revStr.append(stack.pop());
revStr.append(" ");
} // System.out.println("original String:"+input);
System.out.println("\nReverse String : " + revStr);
} }
Or
String str =new String("Happy Birthday to you");
StringBuffer sb = new StringBuffer("str");
StringBuffer sb1 = sb.reverse();
System.out.print(sb1);
About Static
Static class ?
A class cannot be declared static. But a class can be said a static class
if all the variables and methods of the class are static and the
constructor is private. Making the constructor private will prevent the
class to be instantiated. So the only possibility to access is using Class
name only
Static Keyword
Static keyword can be used with the variables and methods but not
with the class but there are static class. Anything declared as static is
related to class and not objects.
Static variable :
Multiples objects of a class shares the same instance of a static
variable.Consider the example:
public class Counter{
private static int count=0;
private int nonStaticcount=0;
public void incrementCounter(){
count++;
nonStaticcount++;
}
public int getCount(){
return count;
}
public int getNonStaticcount(){
return nonStaticcount;
}
public static void main(String args[]){
Counter countObj1 = new Counter();
Counter countObj2 = new Counter();
countObj1.incrementCounter();
countObj1.incrementCounter();
System.out.println("Static count for Obj1: "+countObj1.getCount());
System.out.println("NonStatic count for Obj1: "+countObj1.getNonStaticcount());
System.out.println("Static count for Obj2: "+countObj2.getCount())
System.out.println("NonStatic count for Obj2: "+countObj2.getNonStaticcount())
}
Output
Static count for Obj1: 2
NonStatic count for Obj1: 2
Static count for Obj2: 2
NonStatic count for Obj2: 0
In the above program obj1 and obj2 share the same instance of static
variable count hence if the value is incremented by one object , the
incremented value will be reflected across the other objects.
Static method?
A method defined as static is called static method. A static method can
be accessed without creating the objects. Just by using the Class
name the method can be accessed.
Static method can only access static variables and not local or global
non-static variables. For eg:
public class Test{
public static void printMe(){
System.out.println("Hello World");
}
}
public class MainClass{
public static void main(String args[]){
Test.printMe()
}
}
OutPut:
Hello World
Also static method can call only static methods and not non static
methods. But non-static methods can call static mehtods.
Can static block throw exception?
Yes, static block can throw only Runtime exception or can use a try-
catch block to catch checked exception.
Typically scenario will be if JDBC connection is created in static block
and it fails then exception can be caught, logged and application can
exit. If System.exit () is not done, then application may continue and
next time if the class is referred JVM will throw
NoClassDefFounderror since the class was not loaded by the
Classloader
Difference
between static methods and instance methods?
instance method belongs to the instance of a class therefore it
requires an instance before it can be invoked, whereas static method
belongs to the class itself and not to any class instance so it doesn’t
need an instance to be invoked.
Instance methods use dynamic (late) binding, whereas static
methods use static (early) binding.
When the JVM invokes a class instance method, it selects the method
to invoke based on the type of the object reference, which is always
known at run-time. On the other hand, when the JVM invokes a static
method, it selects the method to invoke based on the actual class of
the object, which may only be known at compile time.
Dynamic binding and static binding?
Method invocation:
The Java programming language provides two basic kinds of methods:
instance methods and class (or static) methods. The difference is:
1. Instance methods require an instance before they can be invoked,
whereas class methods do not.
2. Instance methods use dynamic (late) binding, whereas class
methods use static (early) binding.
When the Java virtual machine invokes a class method, it selects the
method to invoke based on the type of the object reference, which is
always known at compile-time. On the other hand, when the virtual
machine invokes an instance method, it selects the method to invoke
based on the actual class of the object, which may only be known at
run time.
Difference between instanceof and isinstance(Object
obj)?
instanceof is a reserved word of Java, but isInstance(Object obj) is a
method of java.lang.Class.
if (obj instanceof MyType) {
...
}else if (MyType.class.isInstance(obj)) {
...
}
instanceof is used of identify whether the object is type of a
particular class or its subclass but isInstance(obj) is used to identify
object of a particular class.
Difference between equals() and ==?
== operator is used to compare the references of the objects.
public bollean equals(Object o) is the method provided by the Object
class. The default implementation uses == operator to compare two
objects. But since the method can be overriden like for String class.
equals() method can be used to compare the values of two
objects.
String str1 = "MyName";
String str2 = "MyName";
String str3 = str2;
if(str1 == str2){
System.out.println("Objects are equal") }
else{
System.out.println("Objects are not equal")
}
if(str1.equals(str2)){
System.out.println("Objects are equal")
}else{
System.out.println("Objects are not equal")
}
Output:
Objects are not equal
Objects are equal
_______________
String str2 = "MyName";
String str3 = str2;
if(str2 == str3){
System.out.println("Objects are equal")
}else{
System.out.println("Objects are not equal")
}
if(str3.equals(str2)){
System.out.println("Objects are equal")
}else{
System.out.println("Objects are not equal")
}
OutPut:
Objects are equal
Objects are equal.
Can an abstract class have a static method?
Yes an abstract class have a static method and it can be accessed by
any other class(even not a concrete class).
Why static methods cannot access non static variables
or methods?
A static method cannot access non static variables or methods
because static methods don’t need the object to be accessed. So if a
static method has non static variables or non static methods which
has instantiated variables they will no be intialized since the object is
not created and this could result in an error.
Difference between Static {} block and init {} block?
The static block is loaded when the class is loaded by the JVM for the
1st time only whereas init {} block is loaded every time class is
loaded. Also first the static block is loaded then the init block.
public class LoadingBlocks {
static{
System.out.println("Inside static");
}
{
System.out.println("Inside init");
}
public static void main(String args[]){
new LoadingBlocks();
new LoadingBlocks();
new LoadingBlocks();
}
}
Output:
Inside static
Inside init
Inside init
Inside init.
Does a static nested class have access to the enclosing
class' non-static methods or instance variables?
No.
If you compile a file containing inner class how
many .class files are created and what are all of them
accessible in usual way?
If a inner class enclosed with an outer class is compiled then
one .class file for each inner class an a .class file for the outer class is
created.
e.g.
class EnclosingOuter {
class Inner{ }
}
If you compile the above code with command
% javac EnclosingOuter.java
Two files
EnclosingOuter.class
EnclosingOuter$Inner.class
will be created. Though a separate inner class file is generated, the
inner class file is not accessible in the usual way like, % java
EnclosingOuter$Inner.
How to access the inner class from code within the
outer class?
The inner class is instantiated only through the outer class instance.
class EnclosingOuter {
private int noInnerClass = 1;
public void getNoOfInnerClasses(){
Inner in = new Inner();
System.out.println(“No Of Inner classes is :
“+ in.getNoOfClassesFromOuter());
}
class Inner{
public int getNoOfClassesFromOuter(){ return noInnerClass; }
}
Here the method getNoOfInnerClasses() is called on the outer class’s
instance through this outer class instance the inner class instance in
is created.
How to create an inner class instance from outside the
outer class instance code?
To create an instance of the inner class you must have the
instance of its enclosing class.
e.g. class EnclosingOuter {
class Inner{ }
}
To create the instance of inner class from class other than the
enclosing class.
1) class OtherThanOuter{
EnclosingOuter out = new EnclosingOuter();
EnclosingOuter.Inner in = out.new Inner();
}
2) class OtherThanOuter{
EnclosingOuter.Inner out = new EnclosingOuter.Inner (); }
Are the static variables saved as the part of
serialization?
No. The static variables belong to the class and not to an object they
are not the part of the state of the object so they are not saved as the
part of serialized object.
Immutable class?
Immutable class is a class which once created, it’s contents can not be
changed. Immutable objects are the objects whose state can not be
changed once constructed. e.g. String class.
Create an immutable class?
To create an immutable class following steps should be followed:
1. Create a final class.
2. Set the values of properties using constructor only.
3. Make the properties of the class final and private
4. Do not provide any setters for these properties.
5. If the instance fields include references to mutable objects,
don't allow those objects to be changed:
1. Don't provide methods that modify the mutable objects.
2. Don't share references to the mutable objects. Never store
references to external, mutable objects passed to the
constructor; if necessary, create copies, and store
references to the copies. Similarly, create copies of your
internal mutable objects when necessary to avoid
returning the originals in your methods.
E.g.
public final class FinalPersonClass {
private final String name;
private final int age;
public FinalPersonClass(final String name, final int age) {
super();
this.name = name;
this.age = age;
}
public int getAge() {
return age;
}
public String getName() {
return name;
}
Immutable objects:
Immutable objects are simply objects whose state (the object's data)
cannot change after construction. Examples of immutable objects
from the JDK include String and Integer.
Immutable objects greatly simplify your program, since they :
are simple to construct, test, and use
are automatically thread-safe and have no synchronization
issues
do not need a copy constructor
do not need an implementation of clone
allow hashCode to use lazy initialization, and to cache its return
value
do not need to be copied defensively when used as a field
make good Map keys and Set elements (these objects must not
change state while in the collection)
have their class invariant established once upon construction,
and it never needs to be checked again
always have "failure atomicity" (a term used by Joshua Bloch) : if
an immutable object throws an exception, it's never left in an
undesirable or indeterminate state
Immutable objects have a very compelling list of positive qualities.
Without question, they are among the simplest and most robust kinds
of classes you can possibly build. When you create immutable classes,
entire categories of problems simply disappear.
Immutable objects are automatically thread-safe –
true/false?
True. Since the state of the immutable objects can not be changed
once they are created they are automatically synchronized/thread-
safe.
Which classes in java are immutable?
All wrapper classes in java.lang are immutable –
String, Integer, Boolean, Character, Byte, Short, Long, Float, Double,
BigDecimal, BigInteger.
Advantages of immutability?
Ans) The advantages are:
1) Immutable objects are automatically thread-safe, the overhead
caused due to use of synchronisation is avoided.
2) Once created the state of the immutable object can not be changed
so there is no possibility of them getting into an inconsistent state.
3) The references to the immutable objects can be easily shared or
cached without having to copy or clone them as there state can not be
changed ever after construction.
4) The best use of the immutable objects is as the keys of a map
How to make sure that Childclass method actually
overrides the method of the superclass?
Ans) The @Override annotation can be added to the javadoc for the
new method. If you accidently miss an argument or capitalize the
method name wrong, the compiler will generate a compile-time error.
Explain re-entrant, recursive and idempotent
methods/functions?
A method in stack is re-entrant allowing multiple concurrent
invocations that do not interfere with each other.
A function is recursive if it calls itself. Given enough stack space,
recursive method calls are perfectly valid in Java though it is tough to
debug. Recursive functions are useful in removing iterations from
many sorts of algorithms. Allrecursive functions are re-entrant but not
all re-entrant functions are recursive.
Idempotent methods are methods, which are written in such a way
that repeated calls to the same method with the same arguments yield
same results. For example clustered EJBs, which are written with
idempotent methods, can automatically recover from a server failure
as long as it can reach another server.
Can a private variable or method of a class can be
accessed?
Yes its possible using reflection.
When an obj is passed through a function, one can set
the properties but cannot set a new memory location?
Ans) It is because when u pass an object the address value is passed
and stored in some new address . like if address 1234 is passed , it is
stored in 4567 location. So if u change in the value of an object it will
take the address from 4567 and do 1234.setXXX(). If u set the object
to null it will set 4567=null.
About Threads Related
Thread?
In Java, “thread” means two different things: An instance of class
java.lang.Thread.
A thread of execution: An instance of Thread is just…an object.
Like any other object in Java, it has variables and methods, and lives
and dies on the heap. But a thread of execution is an individual
process (a “lightweight” process) that has its own call stack. In Java,
there is one thread per call stack—or, to think of it in reverse, one call
stack per thread. Even if you don’t create any new threads in your
program, threads are back there running.
The main() method, that starts the whole ball rolling, runs in one
thread, called (surprisingly) the main thread. If you looked at the main
call stack (and you can, any time you get a stack trace from something
that happens after main begins, but not within another thread), you’d
see that main() is the first method on the stack— the method at the
bottom. But as soon as you create a new thread, a new stack
materializes and methods called from that thread run in a call stack
that’s separate from the main() call stack.
What is difference between thread and process?
Differences between threads and processes are:-
1. Threads share the address space of the process that created it;
processes have their own address.
2. Threads have direct access to the data segment of its process;
processes have their own copy of the data segment of the parent
process.
3. Threads can directly communicate with other threads of its
process; processes must use interprocess communication to
communicate with sibling processes.
4. Threads have almost no overhead; processes have considerable
overhead.
5. New threads are easily created; new processes require duplication
of the parent process.
6. Threads can exercise considerable control over threads of the same
process; processes can only exercise control over child processes.
7. Changes to the main thread (cancellation, priority change, etc.)
may affect the behavior of the other threads of the process; changes
to the parent process do not affect child processes.
What are the advantages or usage of threads?
Threads support concurrent operations. For example,
• Multiple requests by a client on a server can be handled as an
individual client thread.
• Long computations or high-latency disk and network operations can
be handled in the background without disturbing foreground
computations or screen updates.
Threads often result in simpler programs.
• In sequential programming, updating multiple displays normally
requires a big while-loop that performs small parts of each display
update. Unfortunately, this loop basically simulates an operating
system scheduler. In Java, each view can be assigned a thread to
provide continuous updates.
• Programs that need to respond to user-initiated events can set up
service routines to handle the events without having to insert code in
the main routine to look for these events.
Threads provide a high degree of control.
• Imagine launching a complex computation that occasionally takes
longer than is satisfactory. A “watchdog” thread can be activated that
will “kill” the computation if it becomes costly, perhaps in favor of an
alternate, approximate solution. Note that sequential programs must
muddy the computation with termination code, whereas, a Java
program can use thread control to non-intrusively supervise any
operation.
Threaded applications exploit parallelism.
• A computer with multiple CPUs can literally execute multiple
threads on different functional units without having to simulating
multi-tasking (“time sharing”).
• On some computers, one CPU handles the display while another
handles computations or database accesses, thus, providing extremely
fast user interface response times.
What are the two ways of creating thread?
There are two ways to create a new thread.
1) Extend the Thread class and override the run() method in
your class. Create an instance of the subclass and invoke the start()
method on it, which will create a new thread of execution. e.g.
public class NewThread extends Thread{
public void run()
{
//the code that has to be executed in a separate new thread goes here
}
public static void main(String [] args)
{
NewThread c = new NewThread();
c.start();
}
}
2) Implements the Runnable interface. The class will have to
implement the run() method in the Runnable interface. Create an
instance of this class. Pass the reference of this instance to the Thread
constructor a new thread of execution will be created. e.g. class
public class NewThread implements Runnable{
public void run(){
// the code that has to be executed in a separate new thread goes here
}
public static void main(String [] args){
NewThread c = new NewThread();
Thread t = new Thread(c);
t.start();
}
}
What are the different states of a thread’s lifecycle?
The different states of threads are as follows:
1) New – When a thread is instantiated it is in New state until the
start() method is called on the thread instance. In this state the thread
is not considered to be alive.
2) Runnable – The thread enters into this state after the start method
is called in the thread instance. The thread may enter into the
Runnable state from Running state. In this state the thread is
considered to be alive.
3) Running – When the thread scheduler picks up the thread from the
Runnable thread’s pool, the thread starts running and the thread is
said to be in Running state.
4) Waiting/Blocked/Sleeping – In these states the thread is said to
be alive but not runnable. The thread switches to this state because of
reasons like wait method called or sleep method has been called on
the running thread or thread might be waiting for some i/o resource
so blocked.
5) Dead – When the thread finishes its execution i.e. the run()
method execution completes, it is said to be in dead state. A dead
state can not be started again. If a start() method is invoked on a dead
thread a runtime exception will occur.
What is use of synchronized keyword?
Synchronized keyword can be applied to static/non-static methods or
a block of code. Only one thread at a time can access synchronized
methods and if there are multiple threads trying to access the same
method then other threads have to wait for the execution of method
by one thread. Synchronized keyword provides a lock on the object
and thus prevents race condition. E.g.
public void synchronized method(){}
public void synchronized staticmethod(){}
public void myMethod(){
synchronized (this)
{
// synchronized keyword on block of code
}
}
What is the difference when the synchronized keyword
is applied to a static method or to a non static
method?
When a synch non static method is called a lock is obtained on the
object. When a synch static method is called a lock is obtained on the
class and not on the object. The lock on the object and the lock on the
class don’t interfere with each other. It means, a thread accessing a
synch non static method, then the other thread can access the synch
static method at the same time but can’t access the synch non static
method.
What is a volatile keyword?
In general each thread has its own copy of variable, such that one
thread is not concerned with the value of same variable in the other
thread. But sometime this may not be the case. Consider a scenario in
which the count variable is holding the number of times a method is
called for a given class irrespective of any thread calling, in this case
irrespective of thread access the count has to be increased so the
count variable is declared as volatile. The copy of volatile variable is
stored in the main memory, so every time a thread access the variable
even for reading purpose the local copy is updated each time from the
main memory. The volatile variable also have performance issues.
What is the difference between yield() and sleep()?
yield() allows the current thread to release its lock from the object
and scheduler gives the lock of the object to the other thread with
same priority.
sleep() allows the thread to go to sleep state for x milliseconds. When
a thread goes into sleep state it doesn’t release the lock.
What is the difference between wait() and sleep()?
Both wait() and sleep() are the methods of Object class.
sleep() allows the thread to go to sleep state for x milliseconds. When
a thread goes into sleep state it doesn’t release the lock. wait() allows
thread to release the lock and goes to suspended state. The thread is
only active when a notify() or notifAll() method is called for the same
object.
What is difference between notify() and notfiyAll()?
notify( ) wakes up the first thread that called wait( ) on the same
object.
notifyAll( ) wakes up all the threads that called wait( ) on the same
object. The
highest priority thread will run first.
What happens if a start method is not invoked and the
run method is directly invoked?
If a thread has been instantiated but not started its said to be in new
state. Unless until a start() method is invoked on the instance of the
thread, it will not said to be alive. If you do not call a start() method
on the newly created thread instance thread is not considered to be
alive. If the start() method is not invoked and the run() method is
directly called on the Thread instance, the code inside the run()
method will not run in a separate new thread but it will start running
in the existing thread.
What happens when start() is called?
A new thread of execution with a new call stack starts. The state of
thread changes from new to Runnable. When the thread gets chance
to execute its target run() method starts to run.
If code is running a thread, creates a new thread what
will be the initial priority of the newly created thread?
When a code running in a thread creates a new thread object , the
priority of the new thread is set equal to the priority of the thread
which has created it.
When jvm starts up, which thread will be started up
first?
When jvm starts up the thread executing main method is started.
What are the daemon threads?
Daemon thread are service provider threads run in the
background,these not used to run the application code
generally.When all user threads(non-daemon threads) complete their
execution the jvm exit the application whatever may be the state of
the daemon threads. Jvm does not wait for the daemon threads to
complete their execution if all user threads have completed their
execution.
To create Daemon thread set the daemon value of Thread using
setDaemon(boolean value) method. By default all the threads created
by user are user thread. To check whether a thread is a Daemon
thread or a user thread use isDaemon() method.
Example of the Daemon thread is the Garbage Collector run by jvm to
reclaim the unused memory by the application. The Garbage collector
code runs in a Daemon thread which terminates as all the user
threads are done with their execution.
What all constructors are present in the Thread class?
Thread()
Thread(Runnable target)
Thread(Runnable target, String name)
Thread(String name)
Can the variables or classes be Synchronized?
No. Only methods can be synchronized.
How many locks does an object have?
Each object has only one lock.
Can a class have both Synchronized and non-
synchronized methods?
Yes a class can have both synchronized and non-synchronized
methods.
If a class has a synchronised method and non-
synchronised method, can multiple threads execute
the non-synchronised methods?
Yes. If a class has a synchronised and non-synchronised methods,
multiple threads can access the non-synchronised methods.
If a thread goes to sleep does it hold the lock?
Yes when a thread goes to sleep it does not release the lock.
Can a thread hold multiple locks at the same time?
Yes. A thread can hold multiple locks at the same time. Once a thread
acquires a lock and enters into the synchronized method / block, it
may call another synchronized method and acquire a lock on another
object.
Can a thread call multiple synchronized methods on
the object of which it hold the lock?
Yes. Once a thread acquires a lock in some object, it may call any
other synchronized method of that same object using the lock that it
already holds.
Can static methods be synchronized?
Yes. As static methods are class methods and have only one copy of
static data for the class, only one lock for the entire class is required.
Every class in java is represented by java.lang.Class instance. The
lock on this instance is used to synchronize the static methods.
Can two threads call two different static synchronized
methods of the same class?
No. The static synchronized methods of the same class always block
each other as only one lock per class exists. So no two static
synchronized methods can execute at the same time.
Does a static synchronized method block a non-static
synchronized method?
No As the thread executing the static synchronized method holds a
lock on the class and the thread executing the non-satic synchronized
method holds the lock on the object on which the method has been
called, these two locks are different and these threads do not block
each other.
Once a thread has been started can it be started
again?
No. Only a thread can be started only once in its lifetime. If you try
starting a thread which has been already started once an
IllegalThreadStateException is thrown, which is a runtime exception.
A thread in runnable state or a dead thread can not be restarted.
When does deadlock occur and how to avoid it?
When a locked object tries to access a locked object which is trying to
access the first locked object. When the threads are waiting for each
other to release the lock on a particular object, deadlock occurs.
What is a better way of creating multithreaded
application? Extending Thread class or implementing
Runnable?
If a class is made to extend the thread class to have a multithreaded
application then this subclass of Thread can’t extend any other class
and the required application will have to be added to this class as it
can’t be inherited from any other class. If a class is made to
implement Runnable interface, then the class can extend other class
or implement other interface.
What is multithreading and what are the methods for
inter-thread communication and what is the class in
which these methods are defined?-
Multithreading is the mechanism in which more than one thread run
independent of each other within the process. wait (), notify () and
notifyAll() methods can be used for inter-thread communication and
these methods are in Object class. wait() : When a thread executes a
call to wait() method, it surrenders the object lock and enters into a
waiting state. notify() or notifyAll() : To remove a thread from the
waiting state, some other thread must make a call to notify() or
notifyAll() method on the same object.
Can the start() method of the Thread class be
overridden? If yes should it be overridden?
Yes the start() method can be overridden. But it should not be
overridden as it’s implementation in thread class has the code to
create a new executable thread and is specialised.
What are the methods of the thread class used to
schedule the threads?
public static void sleep(long millis) throws InterruptedException
public static void yield()
public final void join() throws InterruptedException
public final void setPriority(int priority)
public final void wait() throws InterruptedException
public final void notify()
public final void notifyAll()
Which thread related methods are available in Object
class?
public final void wait() throws Interrupted exception
public final void notify()
public final void notifyAll()
Which thread related methods are available in Thread
class?
public static void sleep(long millis) throws Interrupted exception
public static void yield() public final void join() throws Interrupted
exception
public final void setPriority(int priority)
public void start()
public void interrupt()
public final void join()
public void run()
public void resume()
List the methods which when called the thread does
not release the locks held?
notify()
join()
sleep()
yield()
List the methods which when called on the object the
thread releases the locks held on that object?
wait()
Does each thread has its own thread stack?
Yes each thread has its own call stack. For eg
Thread t1 = new Thread();
Thread t2 = new Thread();
Thread t3 = t1;
In the above example t1 and t3 will have the same stack and t2 will
have its own independent stack.
What is thread starvation?
In a multi-threaded environment thread starvation occurs if a low
priority thread is not able to run or get a lock on the resoruce because
of presence of many high priority threads. This is mainly possible by
setting thread priorities inappropriately.
What is threadLocal variable?
ThreadLocal is a class. If a variable is declared as threadLocal then
each thread will have a its own copy of variable and would not
interfere with the other’s thread copy. Typical scenario to use this
would be giving JDBC connection to each thread so that there is no
conflict.
ThreadLocal class by JAVA API
public class ThreadLocal {
public Object get();
public void set(Object newValue);
public Object initialValue();
}
Implementation of ThreadLocal
public class ConnectionDispenser {
private static class ThreadLocalConnection extends ThreadLocal {
public Object initialValue() {
return
DriverManager.getConnection(ConfigurationSingleton.getDbUrl());
}
}
private static ThreadLocalConnection conn = new
ThreadLocalConnection();
public static Connection getConnection() {
return (Connection) conn.get();
}
}
What’s the difference between Thread and Runnable
types?
A Java Thread controls the main path of execution in an application.
When you invoke the Java Virtual Machine with the java command, it
creates an implicit thread in which to execute the main method. The
Thread class provides a mechanism for the first thread to start-up
other threads to run in parallel with it.
The Runnable interface defines a type of class that can be run by a
thread. The only method it requires is run, which makes the interface
very easy to fulfil by extending existing classes. A runnable class may
have custom constructors and any number of other methods for
configuration and manipulation.
How does the run() method in Runnable work?
It may help to think of the run method like the main method in
standard single threaded applications. The run method is a standard
entry point to run or execute a class. The run method is normally only
executed in the context of an independent Thread, but is a normal
method in all other respects.
Why not override Thread to make a Runnable?
There is little difference in the work required to override the Thread
class compared with implementing the Runnable interface, both
require the body of the run() method. However, it is much simpler to
make an existing class hierarchy runnable because any class can be
adapted to implement the run() method. A subclass of Thread cannot
extend any other type, so application-specific code would have to be
added to it rather than inherited.
Separating the Thread class from the Runnable implementation also
avoids potential synchronization problems between the thread and the
run() method. A separate Runnable generally gives greater flexibility
in the way that runnable code is referenced and executed.
When could I adapt the Thread class though?
It is always best to implement a Runnable type rather than extend a
Thread. On that basis, the extension of the Thread class should only
be considered in exceptional circumstances when the application is
very simple, composed of few classes, where the interaction of
threads is minimal and requires only minimal control over thread
execution.
What’s the difference between a thread’s start() and
run() methods?
The separate start() and run() methods in the Thread class provide
two ways to create threaded programs. The start() method starts the
execution of the new thread and calls the run() method. The start()
method returns immediately and the new thread normally continues
until the run() method returns.
The Thread class’ run() method does nothing, so sub-classes should
override the method with code to execute in the second thread. If a
Thread is instantiated with a Runnable argument, the thread’s run()
method executes the run() method of the Runnable object in the new
thread instead.
Depending on the nature of your threaded program, calling the
Thread run() method directly can give the same output as calling via
the start() method, but in the latter case the code is actually executed
in a new thread.
Can I implement my own start() method?
The Thread start() method is not marked final, but should not be
overridden. This method contains the code that creates a new
executable thread and is very specialised. Your threaded application
should either pass a Runnable type to a new Thread, or extend Thread
and override the run() method.
When you will synchronize a piece of your code?-
When you expect your code will be accessed by different threads and
these threads may change a particular data causing data corruption.
What is deadlock?-
When two threads are waiting each other and can’t precede the
program is said to be deadlock.
When a thread cannot acquire a lock on an object?
If a thread attempts to execute a synchronized method or
synchronized statement and is unable to acquire an object's lock, it
enters the waiting state until the lock becomes available.
If all methods are synchronized, is a class thread safe?
Even if all the methods of a class are synchronized, it may still be
vulnerable to thread safety problems if it exposes non-final fields or its
methods return mutable objects that could be manipulated by multiple
threads. Non-final fields should be declared private and encapsulated
with synchronization. Rather than return references to internal object
fields, create an independent copy that has no relation to the original,
known as a deep copy.
A deep copy of an object duplicates the content and state of the
original object and all its constituent fields in such a way that none of
its properties refer to instances in the original at any level.
These measures will help prevent uncontrolled access to the internal
state of objects, but you must also ensure synchronization techniques
are applied in a robust, consistent manner that will not cause
deadlock or race conditions. It is generally better to use synchronized
blocks than synchronized methods for performance reasons. Limit the
extent of synchronized blocks and ensure they all use the same object
monitor.
How do I create a Runnable with inheritance?
To introduce a Runnable type to an existing class hierarchy, you need
to create a sub-class that declares that it implements the Runnable
interface, and provide a run method to fulfil the interface. This
combination of interface and inheritance means that runnable
implementations can be very minor extensions of existing classes
What is Serialization?
Serializable is a marker interface. When an object has to be
transferred over a network ( typically through rmi or EJB) or persist
the state of an object to a file, the object Class needs to implement
Serializable interface. Implementing this interface will allow the
object converted into bytestream and transfer over a network.
Need of Serialization?
To send state of one or more object’s state over the network
through a socket.
To save the state of an object in a file. An object’s state needs to
be manipulated as a stream of bytes.
Externalizable interface?
Externalizable is an interface which contains two methods
readExternal and writeExternal. These methods give you a control
over the serialization mechanism. Thus if your class implements this
interface, you can customize the serialization process by
implementing these methods.
Do we need to implement any method of Serializable
interface to make an object serializable?
No. Serializable is a Marker Interface. It does not have any methods.
To serialize an array or a collection all the members of
it must be serializable. True /False?
True
If a class is serializable but its superclass in not , what
will be the state of the instance variables inherited
from super class after deserialization?
The values of the instance variables inherited from superclass will be
reset to the values they were given during the original construction of
the object as the non-serializable super-class constructor will run.
E.g.
public class ParentNonSerializable {
int noOfWheels;
ParentNonSerializable(){
this.noOfWheels = 4;
}
}
public class ChildSerializable extends ParentNonSerializable
implements Serializable {
private static final long serialVersionUID = 1L;
String color;
ChildSerializable() {
this.noOfWheels = 8;
this.color = "blue";
}
}
public class SubSerialSuperNotSerial {
public static void main(String [] args) {
ChildSerializable c = new ChildSerializable();
System.out.println("Before : - " + c.noOfWheels + " "+ c.color);
try {
FileOutputStream fs = new
FileOutputStream("superNotSerail.ser");
ObjectOutputStream os = new ObjectOutputStream(fs);
os.writeObject(c);
os.close();
} catch (Exception e) { e.printStackTrace(); }
try {
FileInputStream fis = new
FileInputStream("superNotSerail.ser");
ObjectInputStream ois = new ObjectInputStream(fis);
c = (ChildSerializable) ois.readObject();
ois.close();
} catch (Exception e) { e.printStackTrace(); }
System.out.println("After :- " + c.noOfWheels + " "+ c.color);
}}
Result on executing above code –
Before : - 8 blue
After :- 4 blue
The instance variable ‘noOfWheels’ is inherited from superclass which
is not serializable. Therefore while restoring it the non-serializable
superclass constructor runs and its value is set to 8 and is not same as
the value saved during serialization which is 4.
Use of serialVersionUID?
During object serialization, the default Java serialization mechanism
writes the metadata about the object, which includes the class name,
field names and types, and superclass. This class definition is stored
as a part of the serialized object. This stored metadata enables the
deserialization process to reconstitute the objects and map the stream
data into the class attributes with the appropriate type
Everytime an object is serialized the java serialization mechanism
automatically computes a hash value.
ObjectStreamClass's computeSerialVersionUID() method passes the
class name, sorted member names, modifiers, and interfaces to the
secure hash algorithm (SHA), which returns a hash value.The
serialVersionUID is also called suid.
So when the serilaize object is retrieved , the JVM first evaluates
the suid of the serialized class and compares the suid value with the
one of the object. If the suid values match then the object is said to be
compatible with the class and hence it is de-serialized. If
not InvalidClassException exception is thrown.
Changes to a serializable class can be compatible or incompatible.
Following is the list of changes which are compatible:
Add fields
Change a field from static to non-static
Change a field from transient to non-transient
Add classes to the object tree
List of incompatible changes:
Delete fields
Change class hierarchy
Change non-static to static
Change non-transient to transient
Change type of a primitive field
So, if no suid is present , inspite of making compatible changes, jvm
generates new suid thus resulting in an exception if prior release
version object is used .
The only way to get rid of the exception is to recompile and deploy the
application again.
If we explicitly metion the suid using the statement:
private final static long serialVersionUID = <integer value>
then if any of the metioned compatible changes are made the class
need not to be recompiled. But for incompatible changes there is no
other way than to compile again.
Are the static variables saved as the part of
serialization?
No. The static variables belong to the class and not to an object they
are not the part of the state of the object so they are not saved as the
part of serialized object
Result on executing above code –
Before : - 8 blue
After :- 4 blue
The instance variable ‘noOfWheels’ is inherited from superclass which
is not serializable. Therefore while restoring it the non-serializable
superclass constructor runs and its value is set to 8 and is not same as
the value saved during serialization which is 4.
About Garbage Collection:
Which part of the memory is involved in Garbage
Collection? Stack or Heap?
Heap
What is responsibility of Garbage Collector?
Garbage collector frees the memory occupied by the unreachable
objects during the java program by deleting these unreachable
objects.
It ensures that the available memory will be used efficiently, but does
not guarantee that there will be sufficient memory for the program to
run.
Is garbage collector a dameon thread?
Yes GC is a dameon thread. A dameon thread runs behind the
application. It is started by JVM. The thread stops when all non-
dameon threads stop.
Garbage Collector is controlled by whom?
The JVM controls the Garbage Collector; it decides when to run the
Garbage Collector. JVM runs the Garbage Collector when it realizes
that the memory is running low, but this behavior of jvm can’t be
guaranteed.
One can request the Garbage Collection to happen from within the
java program but there is no guarantee that this request will be taken
care of by jvm.
When does an object become eligible for garbage
collection?
An object becomes eligible for Garbage Collection when no live thread
can access it.
What are the different ways to make an object eligible
for Garbage Collection when it is no longer needed?
1. Set all available object references to null once the purpose of
creating the object is served :
public class GarbageCollnTest1 {
public static void main (String [] args){
String str = "Set the object ref to null";
//String object referenced by variable str is not eligible for GC yet
str = null;
/*String object referenced by variable str becomes eligible for GC */
}
}
2. Make the reference variable to refer to another object :
Decouple the reference variable from the object and set it refer to
another object, so the object which it was referring to before
reassigning is eligible for Garbage Collection.
publc class GarbageCollnTest2 {
public static void main(String [] args){
String str1 = "Garbage collected after use";
String str2 = "Another String";
System.out.println(str1);
//String object referred by str1 is not eligible for GC yet
str1 = str2;
/* Now the str1 variable referes to the String object "Another String"
and the object "Garbage collected after use" is not referred by any
variable and hence is eligible for GC */
}
}
3) Creating Islands of Isolation : If you have two instance reference
variables which are referring to the instances of the same class, and
these two reference variables refer to each other and the objects
referred by these reference variables do not have any other valid
reference then these two objects are said to form an Island of
Isolation and are eligible for Garbage Collection.
public class GCTest3 {
GCTest3 g;
public static void main(String [] str){
GCTest3 gc1 = new GCTest3();
GCTest3 gc2 = new GCTest3();
gc1.g = gc2; //gc1 refers to gc2
gc2.g = gc1; //gc2 refers to gc1
gc1 = null;
gc2 = null;
//gc1 and gc2 refer to each other and have no other valid
//references
//gc1 and gc2 form Island of Isolation
//gc1 and gc2 are eligible for Garbage collection here
}
}
Can the Garbage Collection be forced by any means?
No. The Garbage Collection can not be forced, though there are few
ways by which it can be requested there is no guarantee that these
requests will be taken care of by JVM.
How can the Garbage Collection be requested?
There are two ways in which we can request the jvm to execute the
Garbage Collection.
1) The methods to perform the garbage collections are present in the
Runtime class provided by java. The Runtime class is a Singleton for
each java main program.
The method getRuntime() returns a singleton instance of the Runtime
class. The method gc() can be invoked using this instance of Runtime
to request the garbage collection.
2) Call the System class System.gc() method which will request the
jvm to perform GC.
If an object becomes eligible for Garbage Collection
and its finalize() method has been called and inside
this method the object becomes accessible by a live
thread of execution and is not garbage collected. Later
at some point the same object becomes eligible for
Garbage collection, will the finalize() method be called
again?
No
How many times does the garbage collector calls the
finalize() method for an object?
Only once.
What are different ways to call garbage collector?
Garbage collection can be invoked using System.gc() or
Runtime.getRuntime().gc().
About Exceptions
Difference between Error and Exception?
An error is an irrecoverable condition occurring at runtime. Such as
OutOfMemory error. These JVM errors and you can’t repair them at
runtime. Though error can be caught in catch block but the execution
of application will come to a halt and is not recoverable.
While exceptions are conditions that occur because of bad input etc.
e.g. FileNotFoundException will be thrown if the specified file does
not exist. Or a NullPointerException will take place if you try using a
null reference. In most of the cases it is possible to recover from an
exception (probably by giving user a feedback for entering proper
values etc.)
Explain the exception hierarchy in java.
The hierarchy is as follows:
Throwable is a parent class off all Exception classes. They are two
types of Exceptions: Checked exceptions and Unchecked Exceptions.
Both type of exceptions extends Exception class.
Checked exceptions?
Checked exception is those which the Java compiler forces you to
catch. e.g. IOException are checked Exceptions. Checked exception
are the exceptions which forces the programmer to catch them
explicitly in try-catch block. It is a subClass of Exception. Example:
IOException.
Runtime exceptions or Unchecked?
Runtime exceptions are those exceptions that are thrown at runtime
because of either wrong input data or because of wrong business logic
etc. These are not checked by the compiler at compile time.
Unchecked exceptions represent problems that are the result of a
programming problem.
Different ways to handle exceptions?
1. By wrapping the desired code in a try block followed by a catch
block to catch the exceptions.
2. List the desired exceptions in the throws clause of the method and
let the caller of the method handle those exceptions.
In the first approach as a programmer of the method, you
yourselves are dealing with the exception. This is fine if you are in a
best position to decide should be done in case of an exception.
Whereas if it is not the responsibility of the method to deal with its
own exceptions, then do not use this approach. In this case use the
second approach.
In the second approach we are forcing the caller of the method to
catch the exceptions that the method is likely to throw. This is often
the approach library creator’s use. They list the exception in the
throws clause and we must catch them. You will find the same
approach throughout the java libraries we use.
Throw keyword?
Throw keyword is used to throw the exception manually. It is mainly
used when the program fails to satisfy the given condition and it
wants to warn the application. The exception thrown should be
subclass of Throwable.
public void parent(){
try{
child();
}catch(MyCustomException e){ }
}
public void child{
String iAmMandatory=null;
if(iAmMandatory == null){
throw (new MyCustomException("Throwing exception using throw
keyword");
}
}
Throws keyword?
If the function is not capable of handling the exception then it can ask
the calling method to handle it by simply putting the throws
clause at the function declaration.
public void parent(){
try{
child();
}catch(MyCustomException e){ }
}
public void child throws MyCustomException{
//put some logic so that the exception occurs.
}
How to Create custom Exception?
To create you own exception extend the Exception class or any of its
subclasses.
e.g.
1 class New1Exception extends Exception { } // this will create
Checked Exception
2 class NewException extends IOExcpetion { } // this will create
Checked exception
3 class NewException extends NullPonterExcpetion { } // this will
create UnChecked exception
When to make a custom checked Exception or custom
unchecked Exception?
If an application can reasonably be expected to recover from an
exception, make it a checked exception. If an application cannot do
anything to recover from the exception, make it an unchecked
exception.
Once the control switches to the catch block does it
return back to the try block to execute the balance
code?
No. Once the control jumps to the catch block it never returns to the
try block but it goes to finally block(if present).
Where is the clean up code like release of resources is
put in try-catch-finally block and why?
The code is put in a finally block because irrespective of try or catch
block execution the control will flow to finally block. Typically finally
block contains release of connections, closing of result set etc.
Is it valid to have a try block without catch or finally?
NO. This will result in a compilation error. The try block must be
followed by a catch or a finally block. It is legal to omit the either
catch or the finally block but not both.
e.g. The following code is illegal.
try{
int i =0;
}
int a = 2;
System.out.println(“a = “+a);
Is it valid to place some code in between try the
catch/finally block that follows it?
No. There should not be any line of code present between the try and
the catch/finally block. e.g. The following code is wrong.
try{}
String str = “ABC”;
System.out.println(“str = “+str);
catch(Exception e){}
What happens if the exception is never caught and
throws down the method stack?
If the exception is not caught by any of the method in the method’s
stack till you get to the main() method, the main method throws that
exception and the JVM halts its execution.
How do you get the descriptive information about the
Exception occurred during the program execution?
All the exceptions inherit a method printStackTrace() from the
Throwable class. This method prints the stack trace from where the
exception occurred. It prints the most recently entered method first
and continues down, printing the name of each method as it works its
way down the call stack from the top.
Can you catch more than one exceptions in a single
catch block?
Ans)Yes. If the exception class specified in the catch clause has
subclasses, any exception object that is a subclass of the specified
Exception class will be caught by that single catch block.
E.g..
try {
// Some code here that can throw an IOException
}
catch (IOException e) {
e.printStackTrace();
}
The catch block above will catch IOException and all its subclasses
e.g. FileNotFoundException etc.
Exception matching?
Exception matching is the process by which the the jvm finds out the
matching catch block for the exception thrown from the list of catch
blocks. When an exception is thrown, Java will try to find by looking at
the available catch clauses in the top down manner. If it doesn't find
one, it will search for a handler for a supertype of the exception. If it
does not find a catch clause that matches a supertype for the
exception, then the exception is propagated down the call stack. This
process is called exception matching.
What happens if the handlers for the most specific
exceptions is placed above the more general
exceptions handler?
Compilation fails. The catch block for handling the most specific
exceptions must always be placed above the catch block written to
handle the more general exceptions.
e.g. The code below will not compile.
1 try {
// code that can throw IOException or its subtypes
} catch (IOException e) {
// handles IOExceptions and its subtypes
} catch (FileNotFoundException ex) {
// handle FileNotFoundException only
}
The code below will compile successfully :-
try {
// code that can throw IOException or its subtypes
} catch (FileNotFoundException ex) {
// handles IOExceptions and its subtypes
} catch (IOException e){
// handle FileNotFoundException only
}
Is an empty catch block legal?
Yes you can leave the catch block without writing any actual code to
handle the exception caught.
e.g. The code below is legal but not appropriate, as in this case you
will nt get any information about the exception thrown.
try{
//code that may throw the FileNotFoundException
}catch(FileNotFound eFnf){
//no code to handle the FileNotFound exception
}
Can a catch block throw the exception caught by
itself?
Yes. This is called rethrowing of the exception by catch block.
e.g. the catch block below catches the FileNotFound exception and
rethrows it again.
void checkEx() throws FileNotFoundException {
try{
//code that may throw the FileNotFoundException
}catch(FileNotFound eFnf){
throw FileNotFound();
} }
NoClassDefFounderror v/s ClassNotFoundException:
Typically scenario will be if JDBC connection is created in static
block and it fails then exception can be caught, logged and application
can exit. If System.exit() is not done, then application may continue
and next time if the class is referred JVM will throw
NoClassDefFounderror since the class was not loaded by the Class
loader.
A ClassNotFoundException is thrown when the reported class is not
found by the ClassLoader in the CLASSPATH. It could also mean that
the class in question is trying to be loaded from another class which
was loaded in a parent classloader and hence the class from the child
classloader is not visible.
Consider if NoClassDefFoundError occurs which is something like
java.lang.NoClassDefFoundError
src/com/TestClass
does not mean that the TestClass class is not in the CLASSPATH. It
means that the class TestClass was found by the ClassLoader however
when trying to load the class, it ran into an error reading the class
definition. This typically happens when the class in question has static
blocks or members which use a Class that's not found by the
ClassLoader. So to find the culprit, view the source of the class in
question (TestClass in this case) and look for code using static blocks
or static members.
StackOverflowError?
The StackOverFlowError is an Error Object thorwn by the Runtime
System when it Encounters that your application/code has ran out of
the memory. It may occur in case of recursive methods or a large
amount of data is fetched from the server and stored in some object.
This error is generated by JVM.
e.g. void swap(){
swap();
}
What happens if an uncaught exception is thrown
from during the execution of the finalize() method of
an object?
The exception will be ignored and the garbage collection (finalization)
of that object terminates
About Collections
What are the classes implementing List interface?
There are three classes that implement List interface:
1) ArrayList : It is a resizable array implementation. The size of the
ArrayList can be increased dynamically also operations like
add,remove and get can be formed once the object is created. It also
ensures that the data is retrieved in the manner it was stored. The
ArrayList is not thread-safe.
2) Vector: It is thread-safe implementation of ArrayList. The methods
are wrapped around a synchronized block.
3) LinkedList: the LinkedList also implements Queue interface and
provide FIFO(First In First Out) operation for add operation. It is
faster if than ArrayList if it performs insertion and deletion of
elements from the middle of a list.
Arraylist v/s Vector
(http://javarevisited.blogspot.com/2011/05/example-of-arraylist-
in-java-tutorial.html)
Synchronization - ArrayList is not thread-safe whereas Vector is
thread-safe. In Vector class each method like add(), get(int i) is
surrounded with a synchronized block and thus making Vector class
thread-safe.
Data growth - Internally, both the ArrayList and Vector hold onto
their contents using an Array. When an element is inserted into an
ArrayList or a Vector, the object will need to expand its internal array
if it runs out of room. A Vector defaults to doubling the size of its
array, while the ArrayList increases its array size by 50 percent.
Arraylist are not synchronized but if you want to make it
synchronize then you can do like this List list =
Collections.synchronizedList(new ArrayList(...)); While Vectors
are synchronized.
Default increment capacity of Arraylist is 50% while that of Vector
is 100%
i.e. Suppose you have a Arraylist of 10 objects & if 11th object is
added then size of Arraylist will be increased to 15 but in the case of
Vector it would be 20.
Arrays v/s ArrayList ?
Arrays are created of fix size whereas ArrayList is of not fix size. It
means that once array is declared as :
1. int [] intArray= new int[6];
2. intArray[7] // will give ArraysOutOfBoundException.
Also the size of array cannot be incremented or decremented. But
with arrayList the size is variable.
Once the array is created elements cannot be added or deleted from
it. But with ArrayList the elements can be added and deleted at
runtime.
List list = new ArrayList();
list.add(1);
list.add(3);
list.remove(0) // will remove the element from the 1st location.
ArrayList is one dimensional but array can be multidimensional.
int[][][] intArray= new int[3][2][1]; // 3 dimensional array
To create an array the size should be known or initalized to some
value. If not initialized carefully there could me memory wastage. But
arrayList is all about dynamic creation and there is no wastage of
memory
Use of ArrayList or LinkedList ?
Adding new elements is pretty fast for either type of list. For the
ArrayList, doing random lookup using "get" is fast, but for LinkedList,
it's slow. It's slow because there's no efficient way to index into the
middle of a linked list. When removing elements, using ArrayList is
slow. This is because all remaining elements in the underlying array
of Object instances must be shifted down for each remove operation.
But here LinkedList is fast, because deletion can be done simply by
changing a couple of links. So an ArrayList works best for cases
where you're doing random access on the list, and a LinkedList works
better if you're doing a lot of editing in the middle of the list.
ArrayList v/s LinkedList ?
Arraylist is Indexed where as linked list is not.
If you need to support random access, without inserting or removing
elements from any place to other than the end, then ArrayList offers
you the optimal collection, the LinkedList class provides uniformly
named methods to get, remove and insert an element at the beginning
and end of the list.
Each ArrayList instance has a capacity. The capacity is the size of the
array used to store the elements in the list. It is always at least as
large as the list size. As elements are added an ArrayList, its capacity
grows automatically. The details of the growth policy are not specified
beyond the fact that adding an element has constant amortized time
cost.
An application can increase the capacity of an ArrayList instance
before adding a large number of elements using the ensureCapacity
operation. This may reduce the amount of incremental reallocation.
Note that these implementation is not synchronized. If multiple
threads access a set concurrently, and at least one of the threads
modifies the set, it must be synchronized externally. This is typically
accomplished by synchronizing on some object that naturally
encapsulates the set. If no such object exists, the set should be
"wrapped" using the Collections.synchronizedSet method. This is best
done at creation time, to prevent accidental unsynchronized access to
the set:
List list = Collections.synchronizedList(new LinkedList(...));
List list = Collections.synchronizedList(new ArrayList(...));
In List, ArrayList is faster because it is unsynchronized while vector
is synchronized.
In Map, HashMap is faster because it is unsynchronized while
Hahtable is synchronized.
If an ArrayList has to be iterate to read data only,
what are the possible ways and which is the fastest?
It can be done in two ways, using for loop or using iterator of
ArrayList. The first option is faster than using iterator. Because value
stored in arraylist is indexed access. So while accessing the value is
accessed directly as per the index.
If accessing through iterator is slow then why do we
need it and when to use it?
For loop does not allow the updation in the array (add or remove
operation) inside the loop whereas Iterator does. Also Iterator can be
used where there is no clue what type of collections will be used
because all collections have iterator.
Can Arraylist be synchronized without using Vector?
Arraylist can be synchronized using:
Collection.synchronizedList(List list)
Other collections can be synchronized:
Collection.synchronizedMap(Map map)
Collection.synchronizedCollection(Collection c)
I have 100 elements in the array list. i want to delete
from 50 to 100 position how can i do it .please write
the code ?
Use removeRange method from ArrayList
Ex:
al.removeRange(50,101);
50 is include in deletion and 101 is excluded
An Employee class is present and its objects are added
in an arraylist. Now I want the list to be sorted on the
basis of the employeeId of Employee class. What are
the steps?
1) Implement Comparable interface for the Employee class and
override the compareTo ( Object obj) method in which compare the
employeeID
2) Now call Collections.sort() method and pass list as an argument.
Now consider that Employee class is a jar file.
1) Since Comparable interface cannot be implemented, create
Comparator and override the compare(Object obj, Object obj1)
method .
2) Call Collections.sort() on the list and pass comparator as an
argument.
Why is it preferred to declare: List<String> list = new
ArrayList<String>(); instead of ArrayList<String> =
new ArrayList<String>();
It is preferred because:
If later on code needs to be changed from ArrayList to Vector then
only at the declaration place we can do that.
The most important one – If a function is declared such that it takes
list. E.g void showDetails(List list);When the parameter is declared as
List to the function it can be called by passing any subclass of List like
ArrayList,Vector,LinkedList making the function more flexible.
How to make a List (ArrayList,Vector,LinkedList) read
only?
A list implemenation can be made read only
using Collections.unmodifiableList(list). This method returns a
new list. If a user tries to perform add operation on the new list;
UnSupportedOperationException is thrown
I need to use a collection object in my application
which can insert/delete objects at any placed and can
retrieve any particular positioned object in the
collection?
Note: I am not using Threads in my class so don’t
consider about synchronization.?
If you need in a key/value pair then for your requirements HashMap is
best.
If you need just an list which you can use to retrieve values using
index means ArrayList is best.
All the collections are best complexity for solving their own nature
depends on the application requirement.
Difference between HashMap and HashTable?
Both collections implements Map. Both collections store value as key-
value pairs. The key differences between the two are
1. Hashmap is not synchronized in nature but hshtable is.
2. Another difference is that iterator in the HashMap is fail-safe while
the enumerator for the Hashtable isn't.
Fail-safe - “if the Hashtable is structurally modified at any time
after the iterator is created, in any way except through the iterator's
own remove method, the iterator will throw a
ConcurrentModificationException�
3. HashMap permits null values and only one null key, while
Hashtable doesn't allow key or value as null.
(Or)
1. The HashMap class is roughly equivalent to Hashtable, except that
it is non synchronized and permits nulls. (HashMap allows null values
as key and value whereas Hashtable doesn't allow nulls).
2. HashMap does not guarantee that the order of the map will remain
constant over time.
3. HashMap is non synchronized whereas Hashtable is synchronized.
4. Iterator in the HashMap is fail-fast while the enumerator for the
Hashtable is not and throw ConcurrentModificationException if any
other Thread modifies the map structurally by adding or removing
any element except Iterator's own remove() method. But this is not a
guaranteed behavior and will be done by JVM on best effort.
1)Synchronized means only one thread can modify a hash table at
one point of time. Basically, it means that any thread before
performing an update on a hashtable will have to acquire a lock on
the object while others will wait for lock to be released.
2)Fail-safe is relevant from the context of iterators. If an iterator has
been created on a collection object and some other thread tries to
modify the collection object "structurally", a concurrent modification
exception wjavascript:void(0)ill be thrown. It is possible for other
threads though to invoke "set" method since it doesn't modify the
collection "structurally". However, if prior to calling "set", the
collection has been modified structurally, "IllegalArgumentException"
will be thrown.
3)Structurally modification means deleting or inserting element
which could effectively change the structure of map.
HashMap can be synchronized by
Map m = Collections.synchronizeMap(hashMap);
Is it better to have a hashmap with large number of
records or n number of small hashmaps?
It depends on the different scenario one is working on:
1) If the objects in the hashMap are same then there is no point in
having different hashmap as the traverse time in a hashmap is
invariant to the size of the Map.
2) If the objects are of different type like one of Person class , other of
Animal class etc then also one can have single hashmap but different
hashmap would score over it as it would have better readability.
Arrange in the order of speed - HashMap,HashTable,
Collections.synchronizedMap,concurrentHashmap
HashMap is fastest,
ConcurrentHashMap,Collections.synchronizedMap,HashTable.
Difference between List and a Set?
1) List can contain duplicate values but Set doesnt allow. Set allows
only to unique elements.
2) List allows retrieval of data to be in same order in the way it is
inserted but Set doesnt ensures the sequence in which data can be
retrieved.(Except HashSet).
What is identityHashMap?
Ans) The IdentityHashMap uses == for equality checking instead of
equals(). This can be used for both performance reasons, if you know
that two different elements will never be equals and for preventing
spoofing, where an object tries to imitate another.
How to sort list in reverse order?
Ans) To sort the elements of the List in the reverse natural order of
the strings, get a reverse Comparator from the Collections class with
reverseOrder(). Then, pass the reverse Comparator to the sort()
method.
List list = new ArrayList();
Comparator comp = Collections.reverseOrder();
Collections.sort(list, comp)
About Memory Related
Find the maximum size of heap used in the memory in
java.?
find the size of an object?
The heap size of an object can be found using -
Runtime.totalMemory()-Runtime.freeMemory() .
Change the heap size of a JVM?
java -Xms <initial size> -Xmx <maximum size> program
For example:
java -Xms64m -Xmx128m program
Runtime class in java has all the memory related methods.
[b]maxMemory(): [/b]Returns the maximum amount of memory that
the Java virtual machine will attempt to use and
[b]totalMemory():[/b] Returns the total amount of memory in the
Java virtual machine.
Memory leak?
A memory leak is where an unreferenced object that will never be
used again still hangs around in memory and doesnt get garbage
collected.
Consider a scenario in which the admin want to sure
that if some one has written System.exit() at some
part of application then before system shutdown all
the resources should be released. How is it possible?
This is possible
using Runtime.getRuntime().addShutdownHook(Thread hook).
Does Java allocate stack and heap memory?
Each time an object is created in Java it goes into the area of
memory known as heap. The primitive variables like int and double
are allocated in the stack, if they are local method variables and in
the heap if they are member variables (i.e. fields of a class). In Java
methods local variables are pushed into stack when a method is
invoked and stack pointer is decremented when a method call is
completed.
In a multi-threaded application each thread will have its own stack
but will share the same heap. This is why care should be taken in your
code to avoid any concurrent access issues in the heap space. The
stack is threadsafe (each thread will have its own stack) but the heap
is not threadsafe unless guarded with synchronisation through your
code.
Marshling is convert from byte code to network understand able
format .
Unmarshsling is converting from network understand able format
to byte code conversion..
Reference sites:
http://coffeewithcode.com/2011/07/13/java-interview-question-vii/
http://www.precisejava.com/javaperf/j2se/StringAndStringBuffer.htm
http://www.techartifact.com/blogs/2011/07/factory-method-pattern-in-java.html
About Design Patterns
What is Singleton? Have you used Singleton before?
Singleton is a class which has only one instance thought out the
application and provides a getInstance() method to access the
singleton instance.
Step 1: Provide a default Private constructor
Step 2: Create a Method for getting the reference to the
Singleton Object
Step 3: Make the Access method Synchronized to prevent
Thread Problems.
Step 4: Override the Object clone method to prevent
cloning
class SingletonClass {
private static SingletonClass singletonObject;
/** A private Constructor prevents any other class from
instantiating. */
private SingletonClass() {
// Optional Code
}
public static synchronized SingletonClass getSingletonObject()
{
if (singletonObject == null) {
singletonObject = new SingletonClass();
}
return singletonObject;
}
public Object clone() throws CloneNotSupportedException {
throw new CloneNotSupportedException();
}
}
public class SingletonObjectDemo {
public static void main(String args[]) {
// SingletonClass obj = new SingletonClass();
//Compilation error not allowed
SingletonClass obj = SingletonClass.getSingletonObject();
// Your Business Logic
System.out.println("Singleton object obtained");
}
}
How do you prevent for creating another instance of
Singleton using reflection?
Open to all. In my opinion throwing exception from constructor is an
option.
Factory Design Pattern:
Factory Pattern is an interface responsible for creating the
object but the sub classes decides which class to instantiate. It is like
the interface instantiate the appropriate sub-class depending upon the
data passed. Here in this article we will understand how we can
create an Factory Pattern in Java.
When to use a Factory Pattern?
1. When a class does not know which class of objects it must create.
2. A class specifies its sub-classes to specify which objects to create.
3. In programmer’s language (very raw form), you can use factory
pattern where you have to create an object of any one of sub-classes
depending on the data provided.
EG:
In simple words, if we have a super class and n sub-classes, and based
on data provided, we have to return the object of one of the sub-
classes, we use a factory pattern.
Let’s suppose an application asks for entering the name and sex of a
person. If the sex is Male (M), it displays welcome message saying
Hello Mr. <Name> and if the sex is Female (F), it displays message
saying Hello Ms <Name>.
The skeleton of the code can be given here.
public class Person {
// name string
public String name;
// gender : M or F
private String gender;
public String getName() {
return name;
}
public String getGender() {
return gender;
}
}// End of class
This is a simple class Person having methods for name and gender.
Now, we will have two sub-classes, Male and Female which will print
the welcome message on the screen.
public class Male extends Person {
public Male(String fullName) {
System.out.println("Hello Mr. "+fullName);
}
}// End of class
Also, the class Female
public class Female extends Person {
public Female(String fullNname) {
System.out.println("Hello Ms. "+fullNname);
}
}// End of class
Now, we have to create a client, or a SalutationFactory which will
return the welcome message depending on the data provided.
public class SalutationFactory {
public static void main(String args[]) {
SalutationFactory factory = new SalutationFactory();
factory.getPerson(args[0], args[1]);
}
public Person getPerson(String name, String gender) {
if (gender.equals("M"))
return new Male(name);
else if(gender.equals("F"))
return new Female(name);
else
return null;
}
}// End of class
Abstract Factory Pattern:
This pattern is one level of abstraction higher than factory
pattern. This means that the abstract factory returns the factory of
classes. Like Factory pattern returned one of the several sub-classes,
this returns such factory which later will return one of the sub-
classes.
Use of Abstract Factory:
One of the main advantages of Abstract Factory Pattern is that it
isolates the concrete classes that are generated. The names of actual
implementing classes are not needed to be known at the client side.
Because of the isolation, you can change the implementation from one
factory to another.
Eg:
Suppose we need to get the specification of various parts of a
computer based on which work the computer will be used for.
The different parts of computer are, say Monitor, RAM and Processor.
The different types of computers are PC, Workstation and Server.
So, here we have an abstract base class Computer.
package creational.abstractfactory;
public abstract class Computer {
/**
* Abstract method, returns the Parts ideal for Server
* @return Parts
*/
public abstract Parts getRAM();
/**
* Abstract method, returns the Parts ideal for Workstation
* @return Parts
*/
public abstract Parts getProcessor();
/**
* Abstract method, returns the Parts ideal for
* PC
* @return Parts
*/
public abstract Parts getMonitor();
}// End of class
This class, as you can see, has three methods all returning different parts of computer.
They all return a method called Parts. The specification of Parts will be different for
different types of computers. Let’s have a look at the class Parts.
package creational.abstractfactory;
public class Parts {
/**
* specification of Part of Computer, String
*/
public String specification;
/**
* Constructor sets the name of OS
* @param specification of Part of Computer
*/
public Parts(String specification) {
this.specification = specification;
}
/**
* Returns the name of the part of Computer
* @return specification of Part of Computer, String
*/
public String getSpecification() {
return specification;
}
}// End of class
And now lets go to the sub-classes of Computer. They are PC, Workstation and Server.
package creational.abstractfactory;
public class PC extends Computer {
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* Server
* @return Parts
*/
public Parts getRAM() {
return new Parts("512 MB");
}
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* Workstation
* @return Parts
*/
public Parts getProcessor() {
return new Parts("Celeron");
}
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* PC
* @return Parts
*/
public Parts getMonitor() {
return new Parts("15 inches");
}
}// End of class
package creational.abstractfactory;
public class Workstation extends Computer {
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* Server
* @return Parts
*/
public Parts getRAM() {
return new Parts("1 GB");
}
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* Workstation
* @return Parts
*/
public Parts getProcessor() {
return new Parts("Intel P 3");
}
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* PC
* @return Parts
*/
public Parts getMonitor() {
return new Parts("19 inches");
}
}// End of class
package creational.abstractfactory;
public class Server extends Computer{
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* Server
* @return Parts
*/
public Parts getRAM() {
return new Parts("4 GB");
}
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* Workstation
* @return Parts
*/
public Parts getProcessor() {
return new Parts("Intel P 4");
}
/**
* Method over-ridden from Computer, returns the Parts ideal
for
* PC
* @return Parts
*/
public Parts getMonitor() {
return new Parts("17 inches");
}
}// End of class
Now let’s have a look at the Abstract factory which returns a factory
“Computer”. We call the class ComputerType.
package creational.abstractfactory;
/**
* This is the computer abstract factory which returns one
* of the three types of computers.
*
*/
public class ComputerType {
private Computer comp;
public static void main(String[] args) {
ComputerType type = new ComputerType();
Computer computer = type.getComputer("Server");
System.out.println("Monitor:
"+computer.getMonitor().getSpecification());
System.out.println("RAM:
"+computer.getRAM().getSpecification());
System.out.println("Processor:
"+computer.getProcessor().getSpecification());
}
/**
* Returns a computer for a type
*
* @param computerType String, PC / Workstation /
Server
* @return Computer
*/
public Computer getComputer(String computerType) {
if (computerType.equals("PC"))
comp = new PC();
else if(computerType.equals("Workstation"))
comp = new Workstation();
else if(computerType.equals("Server"))
comp = new Server();
return comp;
}
}// End of class
Running this class gives the output as this:
Monitor: 17 inches
RAM: 4 GB
Processor: Intel P 4.
Data Access Object :
Abstracts and encapsulate all access to the data source. The DAO
manages the connection with the data source to obtain and store data.
Base Controller :
Provides a centralized controller for managing the handling of
requests.
Session Facade :
Encapsulate the complexity of interactions between the business
objects participating in a workflow. The Session Facade manages the
business objects, and provides a uniform coarse-grained service
access layer to clients.