The document discusses various topics related to thread management in Java including:
1. Creating and running threads by extending the Thread class or implementing Runnable.
2. Getting and setting thread information like ID, name, priority and status.
3. Interrupting, sleeping, resuming threads and waiting for thread finalization using join().
4. Creating and using daemon threads.
5. Handling unchecked exceptions in threads and using thread-local variables.
6. Grouping threads into thread groups and handling exceptions in a thread group.
7. Implementing a thread factory to centralize thread object creation.
2. All content
1. Basic thread management
2. Thread synchronization mechanisms
3. Thread creation and management
delegation with executors
4. Fork/Join farmework to enhance the
performance of your application
5. Data structures for concurrent programs
6. Adapting the default behavior of some
concurrency classes to your needs
7. Testing Java concurrency applications
3. In this chapter, we will cover:
● Creating and running a thread
● Getting and setting thread information
● Interrupting a thread
● Controlling the interruption of a thread
● Sleeping and resuming a thread
● Waiting for the finalization of a thread
● Creating and running a daemon thread
● Processing uncontrolled exceptions in a
thread
● Using local thread variables
4. ● Grouping threads into a group
● Processing uncontrolled exceptions in a
group of threads
● Creating threads through a factory
5. Creating and running a thread
Threads are Objects. We have two ways of
creating a thread in Java:
● Extending the Thread class and overriding
the run() method
● Building a class that implements the
Runnable interface and then creating an
object of the Thread class passing the
Runnable object as a parameter
6. Creates and runs 10 threads.
Each thread calculates and prints the
mutiplication table of a number between 1 and
10.
11. There’s more...
You can implement a class that extends
Thread class and overrides the run()
method of this class.
Call the start() method to have a new
execution thread.
12. Getting and setting thread
information
The Thread class saves some infomation
attributes that can help us to identify a thread:
● ID: A unique identifier for each Thread.
● Name
● Proiority: The priority of the Thread
objects.
value ∈ [1, 10] (low-->high)
IllegalArgumentException
Not recommended to change, but you can use
if you want.
13. ● Status: Thread can be in one of these six
states (new, runnable, blocked,
waiting, time watiing,
terminated)
You can’t modify the ID and stauts of a thread.
14. Develop a program that establishes the name
and priority for 10 threads, and then show
information about their status until they finish.
22. Interrupting a thread
Finish a program:
● All its non-daemon threads end its
execution.
● One of the threads use the System.exit()
method.
Interruption mechanism
23. Interruption mechanism
Thread has to:
● Check if it has been interrupted or not.
● Decide if it responds to the finalization
request or not.
Thread can ignore it and continue with its
execution.
24. Develop a program that creates Thread and,
after 5 seconds, will force its finalization using
the interruption mechanism.
28. There’s more...
The Thread class has another method to
check whether Thread has been interrupted or
not.
Thread.interrupted()
29. Difference: isInterrupted() and
interrupted()
● interrupted() is static and checks the
current thread.
● isInterrupted() is an instance method
which checks the Thread object that it is
called on.
NOTE:
The second one doesn’t change the
interrupted attribute value, but the first one
set it to false.
33. Controlling the interruption of a
thread
InterruptedException: A better
mechanism to control the interruption of the
thread.
Detect and throw this exception and catch in
the run() method.
34. We will implement Thread that looks for files
with a determined name in a
folder and in all its subfolders to show how to
use the InterruptedException exception
to control the interruption of a thread.
42. Sleeping and resuming a thread
A thread in a program checks a sensor state
once per minute. The rest of the time, the
thread does nothing.
● Thread.sleep()
● TimeUnit.SECONDS.sleep()
43. We will develop a program that uses the
sleep() method to write the actual
date every second.
47. When Thread is sleeping and is interrupted,
the method throws an
InterruptedException
exception immediately and doesn't wait until the
sleeping time finishes.
48. Waiting for the finalization of a
thread
We can use the join() method of the Thread
class.
When we call this method using a thread
object, it suspends the execution of the calling
thread until the object called finishes its
execution.
49. join()
public final void join()
throws InterruptedException
Waits for this thread to die.
join() ==> join(0)
Throws:
InterruptedException - if any thread has
interrupted the current thread. The interrupted
status of the current thread is cleared when this
exception is thrown.
54. If the object thread1 has the code, thread1.
join(1000), the thread2 suspends its
execution until one of these two conditions is
true:
● thread1 finishes its execution
● 1000 milliseconds have been passed
When one of these two conditions is true, the
join() method returns.
57. Creating and running a daemon
thread
Java has a special kind of thread called
daemon thread.
What is daemon thread?
58. Daemon thread
● Very low priority.
● Only executes when no other thread of the
same program is running.
● JVM ends the program finishing these
threads, when daemon threads are the only
threads running in a program.
59. What does daemon thread used for...
Normally used as service providers for normal
threads.
Usually have an infinite loop that waits for the
service request or performs the tasks of the
thread.
They can’t do important jobs.
Example: The java garbage collector.
60. Developing an example with two threads:
● One user thread that writes events on a
queue.
● One daemon thread that cleans the queue,
removing the events which were generated
more than 10 seconds age.
67. How it works...
If you analyze the output of one execution of
the program, you can see how the queue
begins
to grow until it has 30 events and then, its size
will vary between 27 and 30 events until the
end of the execution.
71. How to find out the reason...
● Modify the run() method of WriteTask,
make it easy to distinguish each element.
● Add a scanner, list all element of this deque.
76. Find out the reason...
● ArrayDeque: Not thread-safe
● We can use LinkedBlockingDeque…
Deque<Event> deque = new
LinkedBlockingDeque<Event>();
77. There’s more...
● You only call the setDaemon() method
before you call the start() method. Once
the thread is running, you can’t modify its
daemon status.
● Use isDaemon() method to check if a
thread is a daemon thread or a user thread.
78. Difference between Daemon and
Non Daemon thread in Java :
● JVM doesn't wait for any daemon thread to
finish before existing.
● Daemon Thread are treated differently than
User Thread when JVM terminates, finally
blocks are not called, Stacks are not
unwounded and JVM just exits.
79. Processing uncontrolled exceptions
in a thread
There are two kinds of exceptions in Java:
● Checked exceptions
IOException
ClassNotFoundException
URLReferenceException
● Unchecked exceptions
NumberFormatException
ClassCastException
NullPointException
80. Exceptions in run() method:
● Checked exception:
We have to catch and treat them, because
the run() method doesn't accept a throws
clause.
● Unchecked exception:
A mechanism to catch and treat the
unchecked exceptions.
The default behaviour is to write the stack
trace in the console and exit the program.
87. When an uncaught exception is
thrown in Thread...
JVM looks for…
1. The uncaught exception handler of the
Thread objects.
2. The uncaught exception handler for
ThreadGroup of the Thread objects.
3. The default uncaught exception handler.
None handlers…
The JVM writes the stack trace of the exception
and exits.
88. Using local thread variables
One of the most critical aspects of a concurrent
application is shared data.
If you change an attribute in a thread, all the
threads will be affected by this change.
The Java Concurrency API provides a clean
mechanism called thread-local variables with a
very good performance.
89. We will develop a program that has the
problem and another program using the thread-
local variables mechanism.
96. There’s more...
● protected T initialValue()
● public T get()
● public void set(T value)
● public void remove()
● InheritableThreadLocal
● childValue()
97. InheritableThreadLocal
It provides inheritance of values for threads
created from a thread.
You can override the childValue() method
that is called to initialize the value of the child
thread in the thread-local variable.
101. Grouping threads into a group
ThreadGroup: The threads of a group as a
single unit.
A threadGroup object can be formed by
Thread objects and by another ThreadGroup
object.
A tree structure of threads.
102. Simulating a search...
We will have 5 threads sleeping during a
random period of time, when one of them
finishes, we are going to interrupt the rest.
110. Processing uncontrolled exceptions
in a group of threads
Establish a method that captures all the
uncaught exceptions thrown by any Thread of
the ThreadGroup class.
116. Creating threads through a factory
The factory pattern in OO is a creational
pattern.
Develop an object whose creating other objects
of one or servel classes.
Instead of using the new operator.
Centralize the creation of objects.
117. Some advantages:
● It's easy to change the class of the objects
created or the way we create these objects.
● It's easy to limit the creation of objects for
limited resources. For example, we can only
have n objects of a type.
● It's easy to generate statistical data about
the creation of the objects.
118. Java provides the ThreadFactory interface to
implement a Thread Object factory.
Well will implement a ThreadFactory
interface to create Thread objects with a
personalized name while we save statistics of
the Thread objects created.
123. There’s more...
If you implement a ThreadFactory interface
to centralize the creation of threads, you have
to review the code to guarantee that all threads
are created using that factory.