If two threads are waiting for each other forever such type of infinite waiting is called deadlock in java. Synchronized keyword is the only reason for deadlock situation hence while using synchronized keyword we have to take special care. There is no resolution technique for deadlock, but several prevention techniques are available.
Implementation: Deadlock occurs
Example 1:
// Java program to illustrate Deadlock // where deadlock occurs // Importing required packages import java.io.*;
import java.util.*;
// Class 1 // Helper class class A {
// Method 1 of this class
// Synchronized method
public synchronized void last()
{
// Print and display statement
System.out.println( "Inside A, last() method" );
}
// Method 2 of this class
// Synchronized method
public synchronized void d1(B b)
{
System.out.println(
"Thread1 start execution of d1() method" );
// Try block to check for exceptions
try {
// Putting the current thread to sleep for
// specific time using sleep() method
Thread.sleep( 2000 );
}
// Catch block to handle the exceptions
catch (InterruptedException e) {
// Display the exception on the console
System.out.println(e);
}
// Display statement
System.out.println(
"Thread trying to call B's last() method" );
// Calling the method 1 of this class as created
// above
b.last();
}
} // Class 2 // Helper class B class B {
// Method 1 of this class
public synchronized void last()
{
// Display statement only
System.out.println( "Inside B, last() method" );
}
// Method 2 of this class
// Synchronized the method d2
public synchronized void d2(A a)
{
// Display message only
System.out.println(
"Thread2 start execution of d2() method" );
// Try block to check for exceptions
try {
// Putting the current thread to sleep for
// certain time using sleep() method
Thread.sleep( 2000 );
// Catch block to handle the exceptions
}
catch (InterruptedException e) {
// Display the exception on the console
System.out.println(e);
}
// Display message only
System.out.println(
"Thread2 trying to call A's last method" );
// Again calling the last() method inside this class
a.last();
}
} // Class 3 // Main class // Deadlock class which is extending Thread class class GFG extends Thread {
// Creating object of type class A
A a = new A();
// Creating object of type class B
B b = new B();
// Method 1
public void m1()
{
// Starting the thread
this .start();
// Calling d1 method of class A
a.d1(b);
}
// Method 2
// run() method for the thread
public void run()
{
// Calling d2 method of class B
b.d2(a);
}
// Method 3
// Main driver method
public static void main(String[] args)
{
// Creating object of this class
GFG deadlock = new GFG();
// Calling m1 method
deadlock.m1();
}
} |
Output:
Output explanation:
Here the cursor is showing forever because the threads enter into the deadlock situation. In the above program if we removed at least one synchronized keyword then the program won’t enter into the deadlock situation. Hence, synchronized keyword is one of the major reason for deadlock situation. Due to this while using synchronized keyword we have to take special care.
We can avoid Deadlock situation in the following ways:
- Using Thread.join() Method: We can get a deadlock if two threads are waiting for each other to finish indefinitely using thread join. Then our thread has to wait for another thread to finish, it is always best to use Thread.join() method with the maximum time you want to wait for the thread to finish.
- Use Lock Ordering: We have to always assign a numeric value to each lock and before acquiring the lock with a higher numeric value we have to acquire the locks with a lower numeric value.
- Avoiding unnecessary Locks: We should use locks only for those members on which it is required, unnecessary use of locks leads to a deadlock situation. And it is recommended to use a lock-free data structure and If it is possible to keep your code free from locks. For example, instead of using synchronized ArrayList use the ConcurrentLinkedQueue.
Example 2: Deadlock is prevented
// Java program to illustrate Deadlock // where deadlock is prevented from occurring // Importing required packages import java.io.*;
import java.util.*;
// Class 1 // Helper class class A {
// Method 1 of this class
// Synchronized method
public synchronized void last()
{
// Print and display statement
System.out.println( "Inside A, last() method" );
}
// Method 2 of this class
// Synchronized method
public synchronized void d1(B b)
{
System.out.println(
"Thread1 start execution of d1() method" );
// Try block to check for exceptions
try {
// Putting the current thread to sleep for
// specific time using sleep() method
Thread.sleep( 2000 );
}
// Catch block to handle the exceptions
catch (InterruptedException e) {
// Display the exception on the console
System.out.println(e);
}
// Display statement
System.out.println(
"Thread trying to call B's last() method" );
// Calling the method 1 of this class as created
// above
b.last();
}
} // Class 2 // Helper class B class B {
// Method 1 of this class
public void last()
{
// Display statement only
System.out.println( "Inside B, last() method" );
}
// Method 2 of this class
// Non-synchronized the method d2
public void d2(A a)
{
// Display message only
System.out.println(
"Thread2 start execution of d2() method" );
// Try block to check for exceptions
try {
// Putting the current thread to sleep for
// certain time using sleep() method
Thread.sleep( 2000 );
// Catch block to handle the exceptions
}
catch (InterruptedException e) {
// Display the exception on the console
System.out.println(e);
}
// Display message only
System.out.println(
"Thread2 trying to call A's last method" );
// Again calling the last() method inside this class
a.last();
}
} // Class 3 // Main class // Deadlock class which is extending Thread class class GFG extends Thread {
// Creating object of type class A
A a = new A();
// Creating object of type class B
B b = new B();
// Method 1
public void m1()
{
// Starting the thread
this .start();
// Calling d1 method of class A
a.d1(b);
}
// Method 2
// run() method for the thread
public void run()
{
// Calling d2 method of class B
b.d2(a);
}
// Method 3
// Main driver method
public static void main(String[] args)
{
// Creating object of this class
GFG deadlock = new GFG();
// Calling m1 method
deadlock.m1();
}
} |
Output: