ThreadFactory usage in Java
Some inner workings
The topic is covered quite well except for some inner works that are not easily visible. While creating a thread w/ the constructor the newly created thread inherits current threads:
ThreadGroup
(unless supplied orSystem.getSecurityManager().getThreadGroup()
returns arbitraryThreadGroup
) - The thread group on its right own can be important in some cases and can result in improper thread termination/interruption. TheThreadGroup
will stand as default exception handler.ContextClassLoader
- in managed environment that should not be a great issue since the environment shall switch the CCL, but if you are to implement that - keep it mind. Leaking the caller's CCL is quite bad, so is the thread group (esp. if the threadGroup is some subclass and not directjava.lang.ThreadGroup
- need to overrideThreadGroup.uncaughtException
)AccessControlContext
- here, there is virtually nothing to be done (except starting in a dedicated thread) since the field is for internal usage only, and few even suspect the existence of.- stack size (usually it's unspecified but it can a -fun- thing to get a thread w/ very narrow stack size, based on the caller)
- priority - most people do know about and tend to set it (more or less)
- daemon status - usually that's not very important and easily noticable (if the application just disappears)
- Lastly: the thread inherits caller's
InheritableThreadLocal
- which may (or may not) lead to some implications. Again nothing can be done about, besides spawning the thread into a dedicated thread.
Depending on the application the points above may have no effect at all but in some cases, some of them can lead to Class/Resources leaks that are hard to detect and exhibit not deterministic behavior.
That would make an extra long post but so...
below is some (hopefully) reusable code for ThreadFactory
implementation, it can be used in managed environments to ensure proper ThreadGroup
(which can limit priority or interrupt threads), ContextClassLoader
, stacksize and so on are set (and/or can be configured) and not leaked. If there is any interest I can show how to deal w/ inherited ThreadLocals
or the inherited acc (which essentially can leak the calling classloader
)
package bestsss.util;
import java.lang.Thread.UncaughtExceptionHandler;
import java.security.AccessControlContext;
import java.security.AccessController;
import java.security.PrivilegedAction;
import java.util.concurrent.ThreadFactory;
import java.util.concurrent.atomic.AtomicLong;
public class ThreadFactoryX implements ThreadFactory{
//thread properties
long stackSize;
String pattern;
ClassLoader ccl;
ThreadGroup group;
int priority;
UncaughtExceptionHandler exceptionHandler;
boolean daemon;
private boolean configured;
private boolean wrapRunnable;//if acc is present wrap or keep it
protected final AccessControlContext acc;
//thread creation counter
protected final AtomicLong counter = new AtomicLong();
public ThreadFactoryX(){
final Thread t = Thread.currentThread();
ClassLoader loader;
AccessControlContext acc = null;
try{
loader = t.getContextClassLoader();
if (System.getSecurityManager()!=null){
acc = AccessController.getContext();//keep current permissions
acc.checkPermission(new RuntimePermission("setContextClassLoader"));
}
}catch(SecurityException _skip){
//no permission
loader =null;
acc = null;
}
this.ccl = loader;
this.acc = acc;
this.priority = t.getPriority();
this.daemon = true;//Executors have it false by default
this.wrapRunnable = true;//by default wrap if acc is present (+SecurityManager)
//default pattern - caller className
StackTraceElement[] stack = new Exception().getStackTrace();
pattern(stack.length>1?getOuterClassName(stack[1].getClassName()):"ThreadFactoryX", true);
}
public ThreadFactory finishConfig(){
configured = true;
counter.addAndGet(0);//write fence "w/o" volatile
return this;
}
public long getCreatedThreadsCount(){
return counter.get();
}
protected void assertConfigurable(){
if (configured)
throw new IllegalStateException("already configured");
}
private static String getOuterClassName(String className){
int idx = className.lastIndexOf('.')+1;
className = className.substring(idx);//remove package
idx = className.indexOf('$');
if (idx<=0){
return className;//handle classes starting w/ $
}
return className.substring(0,idx);//assume inner class
}
@Override
public Thread newThread(Runnable r) {
configured = true;
final Thread t = new Thread(group, wrapRunnable(r), composeName(r), stackSize);
t.setPriority(priority);
t.setDaemon(daemon);
t.setUncaughtExceptionHandler(exceptionHandler);//securityException only if in the main group, shall be safe here
//funny moment Thread.getUncaughtExceptionHandler() has a race.. badz (can throw NPE)
applyCCL(t);
return t;
}
private void applyCCL(final Thread t) {
if (ccl!=null){//use factory creator ACC for setContextClassLoader
AccessController.doPrivileged(new PrivilegedAction<Object>(){
@Override
public Object run() {
t.setContextClassLoader(ccl);
return null;
}
}, acc);
}
}
private Runnable wrapRunnable(final Runnable r){
if (acc==null || !wrapRunnable){
return r;
}
Runnable result = new Runnable(){
public void run(){
AccessController.doPrivileged(new PrivilegedAction<Object>(){
@Override
public Object run() {
r.run();
return null;
}
}, acc);
}
};
return result;
}
protected String composeName(Runnable r) {
return String.format(pattern, counter.incrementAndGet(), System.currentTimeMillis());
}
//standard setters allowing chaining, feel free to add normal setXXX
public ThreadFactoryX pattern(String patten, boolean appendFormat){
assertConfigurable();
if (appendFormat){
patten+=": %d @ %tF %<tT";//counter + creation time
}
this.pattern = patten;
return this;
}
public ThreadFactoryX daemon(boolean daemon){
assertConfigurable();
this.daemon = daemon;
return this;
}
public ThreadFactoryX priority(int priority){
assertConfigurable();
if (priority<Thread.MIN_PRIORITY || priority>Thread.MAX_PRIORITY){//check before actual creation
throw new IllegalArgumentException("priority: "+priority);
}
this.priority = priority;
return this;
}
public ThreadFactoryX stackSize(long stackSize){
assertConfigurable();
this.stackSize = stackSize;
return this;
}
public ThreadFactoryX threadGroup(ThreadGroup group){
assertConfigurable();
this.group= group;
return this;
}
public ThreadFactoryX exceptionHandler(UncaughtExceptionHandler exceptionHandler){
assertConfigurable();
this.exceptionHandler= exceptionHandler;
return this;
}
public ThreadFactoryX wrapRunnable(boolean wrapRunnable){
assertConfigurable();
this.wrapRunnable= wrapRunnable;
return this;
}
public ThreadFactoryX ccl(ClassLoader ccl){
assertConfigurable();
this.ccl = ccl;
return this;
}
}
Also some very simple usage:
ThreadFactory factory = new TreadFactoryX().priority(3).stackSize(0).wrapRunnable(false).pattern("Socket workers", true).
daemon(false).finishConfig();
Here's one possible usage:
Assume you have an ExecutorService
which executes your Runnable
tasks in a multithreaded fashion, and once in a while a thread dies from an uncaught exception. Let's also assume that you want to log all of these exceptions. ThreadFactory
solves this problem by allowing you to define a uniform logger for uncaught exceptions in the Runnable
that the thread was executing:
ExecutorService executor = Executors.newSingleThreadExecutor(new LoggingThreadFactory());
executor.submit(new Runnable() {
@Override
public void run() {
someObject.someMethodThatThrowsRuntimeException();
}
});
LoggingThreadFactory
can be implemented like this one:
public class LoggingThreadFactory implements ThreadFactory
{
@Override
public Thread newThread(Runnable r)
{
Thread t = new Thread(r);
t.setUncaughtExceptionHandler(new Thread.UncaughtExceptionHandler()
{
@Override
public void uncaughtException(Thread t, Throwable e)
{
LoggerFactory.getLogger(t.getName()).error(e.getMessage(), e);
}
});
return t;
}
}
The ThreadFactory
interface is a flexible interface that allows the programmer to handle uncaught exceptions as shown above, but also allows much more control over the creation details of a Thread
(like defining a pattern for the thread name) making it quite useful for debugging purposes and production environments alike.
The factory pattern is a creational design pattern used in software development to encapsulate the processes involved in the creation of objects.
Let's assume we have some worker threads for different tasks and want them with special names (say for debugging purposes). So we could implement a ThreadFactory:
public class WorkerThreadFactory implements ThreadFactory {
private int counter = 0;
private String prefix = "";
public WorkerThreadFactory(String prefix) {
this.prefix = prefix;
}
public Thread newThread(Runnable r) {
return new Thread(r, prefix + "-" + counter++);
}
}
If you had such a requirement, it would be pretty difficult to implement it without a factory or builder pattern.
ThreadFactory
is part of the Java API because it is used by other classes too. So the example above shows why we should use 'a factory to create Threads' in some occasions but, of course, there is absolutely no need to implement java.util.concurrent.ThreadFactory
to accomplish this task.