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We all know that in order to invoke Object.wait(), this call must be placed in synchronized block, otherwise an IllegalMonitorStateException is thrown. But what's the reason for making this restriction? I know that wait() releases the monitor, but why do we need to explicitly acquire the monitor by making particular block synchronized and then release the monitor by calling wait()?

What is the potential damage if it was possible to invoke wait() outside a synchronized block, retaining it's semantics - suspending the caller thread?

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5 Answers 5

up vote 61 down vote accepted

A wait() only makes sense when there is also a notify(), so it's always about communication between threads, and that needs synchronization to work correctly. One could argue that this should be implicit, but that would not really help, for the following reason:

Semantically, you never just wait(). You need some condition to be satsified, and if it is not, you wait until it is. So what you really do is

if(!condition){
    wait();
}

But the condition is being set by a separate thread, so in order to have this work correctly you need synchronization.

And there's another thing wrong with it because you can get spurious wakeups, and you could get a notify(), but a third thread makes the condition false again by the time the waiting thread wakes up. So what you really need is always some variation of this:

synchronized(lock){
    while(!condition){
        lock.wait();
    }
}

Better yet, don't mess with the synchronization primitives at all and work with the abstractions offered in the java.util.concurrent packages.

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2  
There's a detailed discussion here as well, saying essentially the same thing. coding.derkeiler.com/Archive/Java/comp.lang.java.programmer/… –  Willie Wheeler May 6 '10 at 8:28
1  
btw, if you are not to ignore interrupted flag the loop shall check Thread.interrupted() as well. –  bestsss Nov 15 '11 at 8:41
1  
I can still do something like: while(!condition){synchronized(this){wait();}} which means there's still a race between checking the condition and waiting even if wait() is correctly called in a synchronized block. So is there any other reason behind this restriction, perhaps due to the way it's implemented in Java? –  shrini1000 Sep 4 '12 at 7:48
1  
A minor point: The third line of the second code block should be lock.wait(); if I'm not mistaken. –  rolve Dec 4 '12 at 20:05
1  
Another nasty scenario: condition is false, we're about to go into wait() and then another thread changes the condition and invokes notify(). Because we're not in wait() yet, we will miss this notify(). In other words, test and wait, as well as change and notify must be atomic. –  Arkadiy Jun 18 at 12:50

What is the potential damage if it was possible to invoke wait() outside a synchronized block, retaining it's semantics - suspending the caller thread?

Let's illustrate what issues we would run into if wait() could be called outside of a synchronized block with a concrete example.

Suppose we were to implement a blocking queue (I know, there is already one in the API :)

A first attempt (without synchronization) could look something along the lines below

class BlockingQueue {
    Queue<String> buffer = new LinkedList<String>();

    public void give(String data) {
        buffer.add(data);
        notify();                   // Since someone may be waiting in take!
    }

    public String take() throws InterruptedException {
        while (buffer.isEmpty())    // don't use "if" due to spurious wakeups.
            wait();
        return buffer.remove();
    }
}

This is what could potentially happen:

  1. A consumer thread calls take() and sees that the buffer.isEmpty().

  2. Before the consumer thread goes on to call wait(), a producer thread comes along and invokes a full give(), that is, buffer.add(data); notify();

  3. The consumer thread will now call wait() (and miss the notify() that was just called).

  4. If unlucky, the producer thread won't produce more give() as a result of the fact that the consumer thread never wakes up, and we have a dead-lock.

Once you understand the issue, the solution is obvious: Always perform give/notify and isEmpty/wait atomically.

Without going into details: This synchronization issue is universal. As Michael Borgwardt points out, wait/notify is all about communication between threads, so you'll always end up with a race condition similar to the one described above. This is why the "only wait inside synchronized" rule is enforced.


A paragraph from the link posted by @Willie summarizes it quite well:

You need an absolute guarantee that the waiter and the notifier agree about the state of the predicate. The waiter checks the state of the predicate at some point slightly BEFORE it goes to sleep, but it depends for correctness on the predicate being true WHEN it goes to sleep. There's a period of vulnerability between those two events, which can break the program.

The predicate that the producer and consumer need to agree upon is in the above example buffer.isEmpty(). And the agreement is resolved by ensuring that the wait and notify are performed in synchronized blocks.

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1  
nice example, thanks –  HaveAGuess Apr 7 '11 at 10:40
3  
Really nice answer +1. –  Eng.Fouad Apr 22 '12 at 12:39
    
In addition also to make sure the changes made to the condition is seen immediately after the wait() finishes, I guess. Otherwise, also a dead-lock since the notify() has been already called. –  Surya Wijaya Madjid Jul 31 '12 at 14:21
1  
This is the answer I was looking for. Thanks for the simple and precise answer. –  dharam Oct 18 '12 at 13:12
1  
Good example, Thanks!! –  AKS Aug 23 '13 at 22:13

@Rollerball is right. Wait() is called, so that the thread can wait for some condition to occur.when this wait() call happens, the thread is forced to give up its lock.
To give up something, you need to own it first.Thread needs to own the lock first. Hence the need to call it inside a synchronized method/block.

Yes, I do agree with all the above answers regarding the potential damages/inconsistencies if you did not check the condition within synchronized method/block. However as @shrini1000 has pointed out, just calling wait() within synchronized block will not avert this inconsistency from happening.

Here is a nice read..

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explain it properly for better understanding of users.. –  Stark Aug 14 '13 at 7:49
    
@Popeye Explain 'properly' properly. Your comment is of no use to anybody. –  EJP Dec 14 '13 at 23:24

directly from this java oracle tutorial:

When a thread invokes d.wait, it must own the intrinsic lock for d — otherwise an error is thrown. Invoking wait inside a synchronized method is a simple way to acquire the intrinsic lock.

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6  
The OP already knew that. The question is "Why?" –  Joachim Sauer May 27 '13 at 8:04
    
From the question the author made, does not seem that the question author has a clear understanding of what I quoted from the tutorial.And moreover, my answer, explains "Why". –  Rollerball May 27 '13 at 12:42
1  
'Otherwise an error is thrown' isn't really 'why'. –  EJP Dec 14 '13 at 23:23

This has to do with hardware architecture (i.e. RAM and caches).

If you don't use synchronized together with wait() or notify() on an object, another thread holding the same object may not see the changements you're doing. Actually, another thread will not see any changements when it already has a copy of the object in the x-level cache (a.k.a. 1st/2nd/3rd-level caches) of the thread handling CPU core.

Hopefully you understand now that above examples are not fully correct, since it doesn't matter who calls wait() or notify() first: Only the local copies of objects in the x-level caches matter, they are the culprit. Moreover I'm convinced that the x-level caches are responsible for most non-reproducible runtime errors. That's because the developers usually don't learn the low-level stuff, like how CPU's work or how the memory hierarchy affects the running of applications: http://en.wikipedia.org/wiki/Memory_hierarchy

It remains a riddle why programming classes don't start with memory hierarchy and CPU architecture first. "Hello world" won't help here. ;)

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Just discovered an website that explains it perfectly and in-depth: javamex.com/tutorials/… –  Marcus Jan 30 at 16:00
    
Hmm.. not sure I follow. If caching was the only reason for putting wait and notify inside synchronized, why isn't the synchronization put inside the implementation of wait / notify? –  aioobe May 18 at 18:07

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