Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

The stop(), suspend(), and resume() in java.lang.Thread are deprecated because they are unsafe. The Sun recommended work around is to use Thread.interrupt(), but that approach doesn't work in all cases. For example, if you are call a library method that doesn't explicitly or implicitly check the interrupted flag, you have no choice but to wait for the call to finish.

So, I'm wondering if it is possible to characterize situations where it is (provably) safe to call stop() on a Thread. For example, would it be safe to stop() a thread that did nothing but call find(...) or match(...) on a java.util.regex.Matcher?

(If there are any Sun engineers reading this ... a definitive answer would be really appreciated.)

EDIT: Answers that simply restate the mantra that you should not call stop() because it is deprecated, unsafe, whatever are missing the point of this question. I know that that it is genuinely unsafe in the majority of cases, and that if there is a viable alternative you should always use that instead.

This question is about the subset cases where it is safe. Specifically, what is that subset?

share|improve this question
@adatapost: Really? I looked at "man pthread_cancel" and it doesn't say it is deprecated. – Stephen C Aug 16 '09 at 4:36
@adatapost: That's simply untrue. Forcibly shutting down a thread or process is not deprecated in any OS I can think of. – Benoit Aug 16 '09 at 5:43
@Fredrik - I thought that the idea was that the target thread has teh control - he can say "not yet"! So pthread_cancel() on the surface appears to do what Stephen wants, but in fact relies on cooperation from the thread. – djna Aug 16 '09 at 6:24
@Vladimir - what about the case where you have a hard requirement to execute untrusted code ... and kill it when it goes bad. There are use-cases where the ability to kill threads is critical. – Stephen C Apr 3 '11 at 22:30
@Vladimir - circular reasoning alert! The primary reason that you should't run untrusted code in the same JVM as your main app is that you can't kill the untrusted code. Sandboxing using a security manager should take care of other concerns. System.exit() can be blocked by the security manager, for example, as can access to external files, the network, use of reflection, and so on – Stephen C Apr 4 '11 at 22:45

Here's my attempt at answering my own question.

I think that the following conditions should be sufficient for a single thread to be safely stopped using Thread.stop():

  1. The thread execution must not create or mutate any state (i.e. Java objects, class variables, external resources) that might be visible to other threads in the event that the thread is stopped.
  2. The thread execution must not use notify to any other thread during its normal execution.
  3. The thread must not start or join other threads, or interact with then using stop, suspend or resume.

(The term thread execution above covers all application-level code and all library code that is executed by the thread.)

The first condition means that a stopped thread will not leave any external data structures or resources in an inconsistent state. This includes data structures that it might be accessing (reading) within a mutex. The second condition means that a stoppable thread cannot leave some other thread waiting. But it also forbids use of any synchronization mechanism other that simple object mutexes.

A stoppable thread must have a way to deliver the results of each computation to the controlling thread. These results are created / mutated by the stoppable thread, so we simply need to ensure that they are not visible following a thread stop. For example, the results could be assigned to private members of the Thread object and "guarded" with a flag that is atomically by the thread to say it is "done".

EDIT: These conditions are pretty restrictive. For example, for a "regex evaluator" thread to be safely stopped, if we must guarantee that the regex engine does not mutate any externally visible state. The problem is that it might do, depending on how you implement the thread!

  1. The Pattern.compile(...) methods might update a static cache of compiled patterns, and if they did they would (should) use a mutex to do it. (Actually, the OpenJDK 6.0 version doesn't cache Patterns, but Sun might conceivably change this.)
  2. If you try to avoid 1) by compiling the regex in the control thread and supplying a pre-instantiated Matcher, then the regex thread does mutate externally visible state.

In the first case, we would probably be in trouble. For example, suppose that a HashMap was used to implement the cache and that the thread was interrupted while the HashMap was being reorganized.

In the second case, we would be OK provided that the Matcher had not been passed to some other thread, and provided that the controller thread didn't try to use the Matcher after stopping the regex matcher thread.

So where does this leave us?

Well, I think I have identified conditions under which threads are theoretically safe to stop. I also think that it is theoretically possible to statically analyse the code of a thread (and the methods it calls) to see if these conditions will always hold. But, I'm not sure if this is really practical.

Does this make sense? Have I missed something?


Things get a bit more hairy when you consider that the code that we might be trying to kill could be untrusted:

  1. We can't rely on "promises"; e.g. annotations on the untrusted code that it is either killable, or not killable.

  2. We actually need to be able to stop the untrusted code from doing things that would make it unkillable ... according to the identified criteria.

I suspect that this would entail modifying JVM behaviour (e.g. implementing runtime restrictions what threads are allowed to lock or modify), or a full implementation of the Isolates JSR. That's beyond the scope of what I was considering as "fair game".

So lets rule the untrusted code case out for now. Or at least, acknowledge that malicious code can do things to render itself not safely killable, and put that problem to one side.

share|improve this answer
The use of reflection APIs would allow the executing code to be selected dynamically, hence potentially defeating the static analysis, so perhaps you would need to prohibit that? – djna Aug 17 '09 at 7:27
If you blow away a thread that happens to be in a synchronized method, and consequently perhaps blocking some other thread, do we know that Java on the death of the first thread will ensure that the other thread will run? – djna Aug 17 '09 at 7:40
The problem for me with static analysis adding information above the documented API is that your application design depends upon "uncontracted" behaviour - the library author has not promised that their next release will not do something (or use another library that does something) unsafe. – djna Aug 17 '09 at 7:44
@djna - in practice, is this any different from the library author changing the contract at the next release and breaking things? Either way, the solution is to do what we always do: analyse / test against all of the releases that we "support" and call the rest "unsupported". – Stephen C Apr 3 '11 at 22:21

The lack of safety comes from the idea idea of critical sections

Take mutex

do some work, temporarily while we work our state is inconsistent

// all consistent now

Release mutex

If you blow away the thread and it happend to be in a critical section then the object is left in an inconsistent state, that means not safely usable from that point.

For it to be safe to kill the thread you need to understand the entire processing of whatever is being done in that thread, to know that there are no such critical sections in the code. If you are using library code, then you may not be able to see the source and know that it's safe. Even if it's safe today it may not be tomorrow.

(Very contrived) Example of possible unsafety. We have a linked list, it's not cyclic. All the algorithms are really zippy because we know it's not cyclic. During our critical section we temporarily introduce a cycle. We then get blown away before we emerge from the critical section. Now all the algorithms using the list loop forever. No library author would do that surely! How do you know? You cannot assume that code you use is well written.

In the example you point to, it's surely possible to write the requreid functionality in an interruptable way. More work, but possible to be safe.

I'll take a flyer: there is no documented subset of Objects and methods that can be used in cancellable threads, because no library author wants to make the guarantees.

share|improve this answer
@djna: Re your last point. I wouldn't rely on documentation anyway. Rather, I'd want to use a static code analysis tool to ensure that a thread can be safely stopped; e.g. see my answer. – Stephen C Aug 17 '09 at 1:57
Java locks held by terminated threads are released, if I remember right. Which doesn't help with the state of lock-protected objects, which may be half-changed. – Vladimir Dyuzhev Apr 3 '11 at 16:14
@Vladimir - that's right. However, if you could figure out that nothing else is going to be influenced by the objects again, then the fact that they are inconsistent would be moot. – Stephen C Apr 4 '11 at 22:49

Maybe there's something I don't know, but as said, it is unsafe because anything this thread is handling is in serious risk to be damaged. Other objects, connections, opened files... for obvious reasons, like "don't shut down your Word without saving first".

For this find(...) exemple, I don't really think it would be a catastrophe to simply kick it away with a sutiless .stop()...

share|improve this answer
Yea ... that is my gut feeling as well. But gut feeling is not good enough when you are trying to build robust servers. – Stephen C Aug 16 '09 at 2:43
It's madness to be calling a deprecated method if anything that isn't for fun. – Noon Silk Aug 16 '09 at 3:00
@silky: it is madness to rule something out just because someone else says it is madness :-) – Stephen C Aug 16 '09 at 4:23
@Stephen C haha, touche, okay I take that :) But in this case it's the Java Designers telling you; and they're more authorative on their language then either of us :) – Noon Silk Aug 16 '09 at 4:53
@silky: But they don't say it is always unsafe, do they? – Stephen C Aug 16 '09 at 5:18

A concrete example would probably help here. If anyone can suggest a good alternative to the following use of stop I'd be very interested. Re-writing java.util.regex to support interruption doesn't count.

import java.util.regex.*;
import java.util.*;

public class RegexInterruptTest {

    private static class BadRegexException extends RuntimeException { }
        final Thread mainThread = Thread.currentThread();
        TimerTask interruptTask = new TimerTask() {
            public void run() {
                System.out.println("Stopping thread.");
                // Doesn't work:
                // mainThread.interrupt();
                // Does work but is deprecated and nasty
                mainThread.stop(new BadRegexException());

        Timer interruptTimer = new Timer(true);
        interruptTimer.schedule(interruptTask, 2000L);

        String s = "aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaab";
        String exp = "(a+a+){1,100}";
        Pattern p = Pattern.compile(exp);
        Matcher m = p.matcher(s);
        try {
            System.out.println("Match: " + m.matches());
        } catch(BadRegexException bre) {
        } finally {
            System.out.println("All over");
share|improve this answer
The only alternative would be to run the regex match in a separate JVM that can be killed. (Which is pretty expensive ... ). However, this looks like the kind of use-case where Thread.stop() might be safe. – Stephen C Jul 7 '10 at 7:35
This is a workaround to a bug (lack of DoS prevention) in the Pattern class. The long-term solution is not to kill a thread, but to fix the Pattern class. – Vladimir Dyuzhev Apr 3 '11 at 19:38
1.6.0_21: no problem with this regexp. Fixed? – Vladimir Dyuzhev Apr 3 '11 at 19:42
@Vladimir - have you heard of the Halting Problem? :-) Now I'm not saying that it is impossible to detect regexes that will behave in a pathological fashion. (I don't know the answer to that.) However, it has been proven that it is impossible to determine if an arbitrary deterministic computation will terminate. So there is a clear need to be able to kill such a computation. – Stephen C Apr 4 '11 at 11:32
No argument there is a practical need to kill a runaway thread. But it doesn't make the kill a safe operation. One may just hope. Besides, it's not always required to find out if a code will take forever. Enough if the code would have a periodic self-checks or callbacks "am I running for too long?" and stops if it is true. – Vladimir Dyuzhev Apr 4 '11 at 21:01

There are ways to use Thread.stop() relatively stable w/o leaking memory or file descriptors (FDs are exceptionally leak prone on *NIX) but you shall rely on it only if you are forced to manage 3rd party code. Never do use it to achieve the result if you can have control over the code itself.

If I use Thread.stop along w/ interrupt() and some more hacks stuff like adding custom logging handlers to re-throw the trapped ThreadDeath, adding unhandleExceltionHandler, running into your own ThreadGroup (sync over 'em), etc...

But that deserves an entire new topic.

But in this case it's the Java Designers telling you; and they're more authorative on their language then either of us :)

Just a note: quite a few of them are pretty clueless

share|improve this answer
I'm sorry, but your answer says nothing about when it is provably safe to use Thread.stop. That's what the question is really about. And the gratuitous insult to the Sun guys isn't helpful either. – Stephen C Dec 27 '10 at 1:28
No need to be sorry. Again you should never use thread.stop() to control the flow of any code you have control of. There are cases with 3rd party libraries that you have no other option but use thread.stop(). If you use custom classloader for the 3rd party library it will be almost always safe to use thread.stop(). Might need to clean stuff (imagine registering jdbc driver) to prevent leaks. I gave another example of using custom logging handlers to prevent code like: for(;;){ try{ .... }catch(Throwable _t){//log here } } – bestsss Jan 2 '11 at 22:34
Forgot: object monitors are not damaged b/c of thread.stop(); – bestsss Jan 2 '11 at 22:56
Upon reflection: the most dangerous about thread.stop() is not leaving any object state inconsistent since you are supposed to be prepared for it and dump anything but exception (ThreadDeath) into class initializers <clinit>. Any exception there makes the class 'broken', this is why the need to a custom classloader to ensure the classes can also be dumped into the void if need be. Plus any singleton and static states can be discarded. Baring that ThreadDeath (i.e. thread.stop()) is not much different from StackOverflowError (nice pun w/ the name of the site) or any other VirtualMachineError. – bestsss Jan 3 '11 at 10:48
"Again you should never use thread.stop() to control the flow of any code you have control of." - If it is provably safe to call Thread.stop() in a given situation, then there is nothing wrong with calling it in that situation. For instance, if Thread.stop() was safe, it would be a better option than checking the interrupted flag all over the place. – Stephen C Sep 22 '11 at 4:31

There is no safe way to kill a thread.

Neither there is a subset of situations where it is safe. Even if it is working 100% while testing on Windows, it may corrupt JVM process memory under Solaris or leak thread resources under Linux.

One should always remember that underneath the Java Thread there is a real, native, unsafe thread.

That native thread works with native, low-level, data and control structures. Killing it may leave those native data structures in an invalid state, without a way to recover.

There is no way for Java machine to take all possible consequences into account, as the thread may allocate/use resources not only within JVM process, but within the OS kernel as well.

In other words, if native thread library doesn't provide a safe way to kill() a thread, Java cannot provide any guarantees better than that. And all known to me native implementations state that killing thread is a dangerous business.

share|improve this answer

If my understanding is right, the problem has to do with synchronization locks not being released as the generated ThreadInterruptedException() propagates up the stack.

Taking that for granted, it's inherently unsafe because you can never know whether or not any "inner method call" you happened to be in at the very moment stop() was invoked and effectuated, was effectively holding some synchronization lock, and then what the java engineers say is, seemingly, unequivocally right.

What I personally don't understand is why it should be impossible to release any synchronization lock as this particular type of Exception propagates up the stack, thereby passing all the '}' method/synchronization block delimiters, which do cause any locks to be release for any other type of exception.

I have a server written in java, and if the administrator of that service wants a "cold shutdown", then it is simply NECESSARY to be able to stop all running activity no matter what. Consistency of any object's state is not a concern because all I'm trying to do is to EXIT. As fast as I can.

share|improve this answer
-1 this is wrong. The problem is that locks are released, but that there is nothing to guarantee that the data-structures they protected are in a consistent state. – Stephen C Aug 17 '09 at 1:12

All forms of concurrency control can be provided by the Java synchronization primitives by constructing more complex concurrency controls that suit your problem.

The reasons for deprecation are clearly given in the link you provide. If you're willing to accept the reasons why, then feel free to use those features.

However, if you choose to use those features, you also accept that support for those features could stop at any time.

Edit: I'll reiterate the reason for deprecation as well as how to avoid them.

Since the only danger is that objects that can be referenced by the stoped thread could be corrupted, simply clone the String before you pass it to the Thread. If no shared objects exist, the threat of corrupted objects in the program outside the stoped Thread is no longer there.

share|improve this answer
@Ben: but what if the complex concurrency solutions simply do not solve the problem? For example:… – Stephen C Aug 16 '09 at 4:34
@Stephen C: I think in such cases, the Thread which requires arbitrary interruption should be implemented as a separate Process instead, and forcibly shut down using termination signals to be done safely. I've added my answer to the question you referred to. – Benoit Aug 16 '09 at 5:35
Even cloning the String doesn't absolutely guarantee safety. You don't know whether the String class does anything clever with the string representations. Does it share buffers for identical strings? Does it cache internal pointers to substrings to optimise searches? When you call myString.find() what processing does it do? – djna Aug 16 '09 at 5:56
@Ben S. What do we "know"? If we have the source we can by inspection determine whether any code used in a thread can safely be cancelled. For each new release of that source we must perform that inspection. But my point here was that in general we don't have the source for libraries, and even apparently trivial interfaces may have deep unsafe complexity. – djna Aug 16 '09 at 6:30
@Ben S. How you create the String is not important to my argument. the String implementation could on construction do all manner of optimisations, such as spotting that it already has seen that array of chars. It could when doing a find() within a String build a little dictionary. We can't infer from the interface what is going on. Simple example of an implementation surprise x = new Integer(8); y = new Integer(8); x and y actually point to the same Integer!! There's a cunning internal optimisation for small Integers. – djna Aug 16 '09 at 6:35

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.