Given that there's only one lock for each instance of a class, then why doesn't Java just allow us to do this:
void method() {
synchronized {
// do something
}
// do other things
}
instead of this:
void method() {
synchronized (lock) {
// do something
}
// do other things
}
What's the purpose of specifying a lock? Does it make a difference if I choose one object as a lock over the other? Or could I just choose any random object?
EDIT:
It turned out that my comprehension of synchronized methods is wrong at the fundamental level.
I thought different synchronized methods or blocks are entirely independent of each other regardless of locks. Rather, all synchronized methods or blocks with the same lock can be accessed only by one thread, even if such synchronized methods/blocks are from different classes (the documentation should have emphasized this more: ALL synced methods/blocks, regardless of location, all that matters is the lock).
Given that there's only one lock for each instance of a class, then why doesn't Java just allow us to do this:
void method() {
synchronized {
// do something
}
// do other things
}
Although an intrinsic lock is provided with each instance,
that's not necessarily the "obvious" lock to use.
You're perhaps right that they could have provided synchronized { ... } as a shorthand for synchronized (this) { ... }.
I don't know why they didn't, but I never missed it.
But concurrent programming is tricky,
so making the lock object an explicit required parameter may make things clearer to readers, which is a good thing, as #ajb pointed out in a comment.
In any case, I don't think syntax is your main question, so let's move on.
What's the purpose of specifying a lock?
Uhm, the lock is perhaps the single most important thing in the synchronization mechanism. The key point in synchronization is that only one thread can hold the same lock. Two threads holding different locks are not synchronized. So knowing what is the lock guarding the synchronization is crucial.
Does it make a difference if I choose one object as a lock over the other?
I hope the previous section makes it clear that yes, you have to choose the object carefully. It has to be an object visible by all threads involved,
it has to be not null, and it has to be something that won't get reassigned during the period of synchronization.
Or could I just choose any random object?
Certainly not. See the previous section.
To understand concurrency in Java, I recommend the book Java Concurrency in Practice by one of the authors of the API, or Oracle's tutorials on the subject.
It's so you can lock on something completely different than this.
Remember how Vector is "thread-safe?" It's not quite that simple; each call is, but code like this isn't because it could have been updated between getting the size of the vector and getting the element:
for (int i = 0; i < vector.size(); ++i) System.out.println(vector.get(i));
Since Vector, along with Collections.synchronized*, is synchronized with the older synchronized keyword, you can make that above code thread-safe by enclosing it all within a lock:
synchronized (vector) {
for (int i = 0; i < vector.size(); ++i) System.out.println(vector.get(i));
}
This could be in a method that isn't thread-safe, isn't synchronized, or uses ReentrantLock; locking the vector is separate from locking this.
It most certainly makes a difference what object you use as a lock. If you say
void method() {
synchronized (x) {
// do something
}
// do other things
}
Now, if one thread is executing the block and another tries to enter the block, if x is the same for both of them, then the second thread will have to wait. But if x is different, the second thread can execute the block at the same time. So, for example, if method is an instance method and you say
void method() {
synchronized (this) {
// do something
}
// do other things
}
Now two threads running the method using the same object can't execute the block simultaneously, but two threads can still run the method on different objects without blocking each other. This is what you'd want when you want to prevent simultaneous access to the instance variables in that object, but you don't have anything else you need to protect. It's not a problem if two threads are accessing variables in two different objects.
But say the block of code is accessing a common resource, and you want to make sure all other threads are locked out of accessing that resource. For example, you're accessing a database, and the block does a series of updates and you want to make sure they're done atomically, i.e. no other code should access the database while you're in between two updates. Now synchronized (this) isn't good enough, because you could have the method running for two different objects but accessing the same database. In this case, you'd need a lock that is the same for all objects that might access the same database. Here, making the database object itself the lock would work. Now no two threads can use method to enter this block at the same time, if they're working with the same database, even if the objects are different.
if you have multiple objects b1/b2 needs to update concurrency
class A {
private B b1, b2;
}
if you have only one lock say class A itself
synchronized (this) { ... }
then assume there are two threads are updating b1 and b2 in the same time, they will play one by one because synchronized (this)
but if you have two locks for b1 and b2
private Object lock1 = new Object, lock2 = new Object;
the two threads i've mentioned will play concurrently because synchronized (lock1) not affect synchronized (lock2).sometimes means better performance.
In synchronized (lock).., lock can be an object level lock or it can be class level lock.
Example1 Class Level Lock:
private static Object lock=new Object();
synchronized (lock){
//do Something
}
Example2 Object Level Lock:
private Object lock=new Object();
synchronized (lock){
//do Something
}
I'm wondering if there is an easy way to make a synchronized lock that will respond to changing references. I have code that looks something like this:
private void fus(){
synchronized(someRef){
someRef.roh();
}
}
...
private void dah(){
someRef = someOtherRef;
}
What I would like to happen is:
Thread A enters fus, and acquires a lock on someref as it calls roh(). Assume roh never terminates.
Thread B enters fus, begins waiting for someRef` to be free, and stays there (for now).
Thread C enters dah, and modifies someRef.
Thread B is now allowed to enter the synchronized block, as someRef no longer refers to the object Thread A has a lock on.
What actually happens is:
Thread A enters fus, and acquires a lock on someref as it calls roh(). Assume roh never terminates.
Thread B enters fus, finds the lock, and waits for it to be released (forever).
Thread C enters dah, and modifies someRef.
Thread B continues to wait, as it's no longer looking at someref, it's looking at the lock held by A.
Is there a way to set this up such that Thread B will either re-check the lock for changing references, or will "bounce off" into other code? (something like sychronizedOrElse?)
There surely is a way, but not with synchronized. Reasoning: At the point in time, where the 2nd thread enters fus(), the first thread holds the intrinsic lock of the object referenced by someRef. Important: the 2nd thread will still see someRef referencing on this very object and will try to acquire this lock. Later on, when the 3rd thread changes the reference someRef, it would have to notify the 2nd thread somehow about this event. This is not possible with synchronized.
To my knowledge, there is no built-in language-feature like synchronized to handle this kind of synchronization.
A somewhat different approach would be to either manage a Lock within your class or give someRef an attribute of type Lock. Instead of working with lock() you can use tryLock() or tryLock(long timeout, TimeUnit unit). This is a scheme on how I would implement this (assuming that someRef has a Lock attribute):
volatile SomeRef someRef = ... // important: make this volatile to deny caching
...
private void fus(){
while (true) {
SomeRef someRef = this.someRef;
Lock lock = someRef.lock;
boolean unlockNecessary = false;
try {
if (lock.tryLock(10, TimeUnit.MILLISECONDS)) { // I have chonse this arbritrarily
unlockNecessary = true;
someRef.roh();
return; // Job is done -> return. Remember: finally will still be executed.
// Alternatively, break; could be used to exit the loop.
}
} catch (InterruptException e) {
e.printStackTrace();
} finally {
if (unlockNecessary) {
lock.unlock();
}
}
}
}
...
private void dah(){
someRef = someOtherRef;
}
Now, when someRef is changed, the 2nd thread will see the new value of someRef in its next cycle and therefore will try to synchronize on the new Lock and succeed, if no other thread has acquired the Lock.
What actually happens is ... Thread B continues to wait, as it's no longer looking at someref, it's looking at the lock held by A.
That's right. You can't write code to synchronize on a variable. You can only write code to synchronize on some object.
Thread B found the object on which to synchronize by looking at the variable someref, but it only ever looks at that variable one time to find the object. The object is what it locks, and until thread A releases the lock on that object, thread B is going to be stuck.
I would like to add some more info on top of excellent answers by #Turing85 and #james large.
I agree that Thread B continues to wait.
It's better to avoid synchronization for this type of program by using better lock free API.
Atomic variables have features that minimize synchronization and help avoid memory consistency errors.
From the code you have posted, AtomicReference seems to be right solution for your problem.
Have a look at documentation page on Atomic package.
A small toolkit of classes that support lock-free thread-safe programming on single variables. In essence, the classes in this package extend the notion of volatile values, fields, and array elements to those that also provide an atomic conditional update operation of the form:
boolean compareAndSet(expectedValue, updateValue);
One more nice post in SE related to this topic.
When to use AtomicReference in Java?
Sample code:
String initialReference = "value 1";
AtomicReference<String> someRef =
new AtomicReference<String>(initialReference);
String newReference = "value 2";
boolean exchanged = someRef.compareAndSet(initialReference, newReference);
System.out.println("exchanged: " + exchanged);
Refer to this jenkov tutorial for better understanding.
I have a class in java that reads UDP packets and puts them in an object (in a basically infinite loop). This object is then accessed in multiple separate threads, but obviously, since it is being filled at the same time, all these getters/setters are in synchronized methods. Problem is, right now these getters have code like this:
public synchronized SomeObject exampleGetter() {
if(this.isReceiving)
return oldCachedObject;
else
return currentObject;
}
Obviously, that's not quite the best way of doing things, so how should I go about writing methods (lots of different ones) that totally lock the object to one thread at a time and block the others (including the thread that created the object in the first place)? I looked at synchronized blocks, but I am kinda confused as to what effect the "lock object" has, is that the object that has access to the block at that given time? Any advice would be appreciated. Thanks!
The synchronized keyword synchronizes on the whole object instance not just the setter. I would rather go for a fine grained locking strategy or better... use a thread safe data structure where you store and get the received data. I personally love the BlockingQueue<T> where T is the type of data you receive on the network.
So suppose you are receiving Objects over a socket:
public class ReceivedDataHolder{
BlockingQueue<Object> dataBuffer = new LinkedBlockingQueue<Object>();
//...
public void dataReceived(Object data){
dataBuffer.offer(data);
}
public Object getReceivedData(){
return dataBuffer.take();
}
}
And in your socket you could do this whenever you receive data:
receivedDataHolder.dataReceived(object);
Any thread that wants to get data should do:
receivedDataHolder.getReceivedData();
This latter method call will block the calling thread until there is an element available on the queue (check this out for more details)
I hope this helps
Maybe AtomicReference would be suitable for you.
See:
java.util.concurrent.atomic
Java volatile reference vs. AtomicReference
All objects in java has something called Intrinsic locks, If any thread wants to do any operation on any object then it needs to acquire the intrinsic lock of that object. it will guarantee that only 1 thread will process your block of code at any given time.
A thread can acquire lock on any object, if that object is not locked by any other thread, if it is locked then the thread will wait till the other thread releases the lock on that object.
if you use synchronized block, your code will be somewhat like this
public void SomeObject exampleGetter() {
synchronized(this)
{
if(this.isReceiving)
return oldCachedObject;
else
return currentObject;
}
In this case when your thread enters the synchronized block, if any other thread is having lock on this object, then it will wait till that thread releases the lock. and if that object is free then your thread will acquire the lock on this object and perform the operation and then release the lock on that object.
for further information on synchronized blocks, methods and intrinsic locks, refer
http://docs.oracle.com/javase/tutorial/essential/concurrency/locksync.html
I hope it helped you :)
I have a little difficulty in understanding the concept of private locks:
public class MyObject {
private final Object lock = new Object(); // private final lock object
public void mymethod() {
synchronized (lock) { // Locks on the private Object
// ...
}
}
}
In the code above, lock is acquired on a different object but the code in the current object is guarded by synchronised block. Now, apart from the lock object in the code above, it could be any other object too. I find it difficult to understand how the lock on another object is related to the synchronised keyword in the current object. IMO, it may lead to some malicious code to lock any object. What is the basis of allowing locks on other objects.
Well you could, for example, have an object that manages two lists.
If its possible for thread A to alter list 1 while thread B alters list 2 then you'd use distinct locks, rather than synchronizing on the owning object.
Essentially explicit locks allow for finer grained control of behavior.
IMO, it may lead to some malicious code to lock any object.
This is the crux of the issue, actually.
With a separate lock object as shown (crucially, with private access) then only code in the MyObject class will be able to acquire a lock on that monitor - so you can see all of the code that might take part in locking situations involving this class.
Going to the other extreme, if you acquire a lock on e.g. a constant String, then any code, anywhere in the same JVM that locks on the same String will contend with your class - which is almost certainly not intended and will be very hard to track down.
Basically - if you lock on a non-private object, that then becomes part of your public interface, effectively. Sometimes this is intended (e.g. for the Collections.synchronizedFoo objects, they declare that one can synchronize on the object itself in order to coarsen your lock). Often it is not and is merely an oversight.
You should keep your lock monitors private, for the same reason you keep private member variables private - to prevent other code messing with things that they shouldn't. And this is basically never private.
You're right, the code you provided could lock on any object. However, it didn't. It locked on a private instance field--a field which only that instance can access. That means that no other code can possibly lock on that object. You didn't, in this case, lock on some other object because if some other code locked on it, then you'd have to wait for it (and it may never be released).
"Malicious" code could lock on any object, but it only hurts other code if that other code attempts to lock on the same object. My creating your own private object to lock on, you protect yourself from locks by other code.
synchronized is actually effective for multithreaded environment. This method is to allow concurrency in your system.
When an object is synchronized, the first thread that "touched" the object puts a lock on that object until that thread that is using the locked object finished using the object and releases it. It prevents many threads to change the same object concurrently.
Locks are always on objects.
purpose of syncronized block is to guard objects (one associated with block) with locks, So this means only thread which has lock for object can enter this block.
There is nothing wrong with it, There can be situation in code where you don't need to synchronize complete method but just few lines of code.
One use of synchronization block is in situation when state of object (and other objects related to it) needs to changed in multi threaded env, But the Class of this object doesn't have synchronized methods to alter state of object.
In such situation synchronization is achieved using such block.
Locks should be private iff there will be no reason for any lock related to your class to be held while no thread is actually running code in your class (or code called from code in your class). If you need to e.g. allow someone to maintain exclusive control over your object between operations, you'll have to expose a lock. This opens up many potential issues, including deadlock, so it's generally best if you can design your interfaces and contracts so as to render such extended locking unnecessary.
BTW, note that performing callbacks while holding a lock is slightly less dangerous than exposing a lock, but only slightly. You would eliminate the danger that a caller might acquire a lock and simply forget about it, but the danger of deadlock would still remain.
Whenever a question pops up on SO about Java synchronization, some people are very eager to point out that synchronized(this) should be avoided. Instead, they claim, a lock on a private reference is to be preferred.
Some of the given reasons are:
some evil code may steal your lock (very popular this one, also has an "accidentally" variant)
all synchronized methods within the same class use the exact same lock, which reduces throughput
you are (unnecessarily) exposing too much information
Other people, including me, argue that synchronized(this) is an idiom that is used a lot (also in Java libraries), is safe and well understood. It should not be avoided because you have a bug and you don't have a clue of what is going on in your multithreaded program. In other words: if it is applicable, then use it.
I am interested in seeing some real-world examples (no foobar stuff) where avoiding a lock on this is preferable when synchronized(this) would also do the job.
Therefore: should you always avoid synchronized(this) and replace it with a lock on a private reference?
Some further info (updated as answers are given):
we are talking about instance synchronization
both implicit (synchronized methods) and explicit form of synchronized(this) are considered
if you quote Bloch or other authorities on the subject, don't leave out the parts you don't like (e.g. Effective Java, item on Thread Safety: Typically it is the lock on the instance itself, but there are exceptions.)
if you need granularity in your locking other than synchronized(this) provides, then synchronized(this) is not applicable so that's not the issue
I'll cover each point separately.
Some evil code may steal your lock (very popular this one, also has an
"accidentally" variant)
I'm more worried about accidentally. What it amounts to is that this use of this is part of your class' exposed interface, and should be documented. Sometimes the ability of other code to use your lock is desired. This is true of things like Collections.synchronizedMap (see the javadoc).
All synchronized methods within the same class use the exact same
lock, which reduces throughput
This is overly simplistic thinking; just getting rid of synchronized(this) won't solve the problem. Proper synchronization for throughput will take more thought.
You are (unnecessarily) exposing too much information
This is a variant of #1. Use of synchronized(this) is part of your interface. If you don't want/need this exposed, don't do it.
Well, firstly it should be pointed out that:
public void blah() {
synchronized (this) {
// do stuff
}
}
is semantically equivalent to:
public synchronized void blah() {
// do stuff
}
which is one reason not to use synchronized(this). You might argue that you can do stuff around the synchronized(this) block. The usual reason is to try and avoid having to do the synchronized check at all, which leads to all sorts of concurrency problems, specifically the double checked-locking problem, which just goes to show how difficult it can be to make a relatively simple check threadsafe.
A private lock is a defensive mechanism, which is never a bad idea.
Also, as you alluded to, private locks can control granularity. One set of operations on an object might be totally unrelated to another but synchronized(this) will mutually exclude access to all of them.
synchronized(this) just really doesn't give you anything.
While you are using synchronized(this) you are using the class instance as a lock itself. This means that while lock is acquired by thread 1, the thread 2 should wait.
Suppose the following code:
public void method1() {
// do something ...
synchronized(this) {
a ++;
}
// ................
}
public void method2() {
// do something ...
synchronized(this) {
b ++;
}
// ................
}
Method 1 modifying the variable a and method 2 modifying the variable b, the concurrent modification of the same variable by two threads should be avoided and it is. BUT while thread1 modifying a and thread2 modifying b it can be performed without any race condition.
Unfortunately, the above code will not allow this since we are using the same reference for a lock; This means that threads even if they are not in a race condition should wait and obviously the code sacrifices concurrency of the program.
The solution is to use 2 different locks for two different variables:
public class Test {
private Object lockA = new Object();
private Object lockB = new Object();
public void method1() {
// do something ...
synchronized(lockA) {
a ++;
}
// ................
}
public void method2() {
// do something ...
synchronized(lockB) {
b ++;
}
// ................
}
}
The above example uses more fine grained locks (2 locks instead one (lockA and lockB for variables a and b respectively) and as a result allows better concurrency, on the other hand it became more complex than the first example ...
While I agree about not adhering blindly to dogmatic rules, does the "lock stealing" scenario seem so eccentric to you? A thread could indeed acquire the lock on your object "externally"(synchronized(theObject) {...}), blocking other threads waiting on synchronized instance methods.
If you don't believe in malicious code, consider that this code could come from third parties (for instance if you develop some sort of application server).
The "accidental" version seems less likely, but as they say, "make something idiot-proof and someone will invent a better idiot".
So I agree with the it-depends-on-what-the-class-does school of thought.
Edit following eljenso's first 3 comments:
I've never experienced the lock stealing problem but here is an imaginary scenario:
Let's say your system is a servlet container, and the object we're considering is the ServletContext implementation. Its getAttribute method must be thread-safe, as context attributes are shared data; so you declare it as synchronized. Let's also imagine that you provide a public hosting service based on your container implementation.
I'm your customer and deploy my "good" servlet on your site. It happens that my code contains a call to getAttribute.
A hacker, disguised as another customer, deploys his malicious servlet on your site. It contains the following code in the init method:
synchronized (this.getServletConfig().getServletContext()) {
while (true) {}
}
Assuming we share the same servlet context (allowed by the spec as long as the two servlets are on the same virtual host), my call on getAttribute is locked forever. The hacker has achieved a DoS on my servlet.
This attack is not possible if getAttribute is synchronized on a private lock, because 3rd-party code cannot acquire this lock.
I admit that the example is contrived and an oversimplistic view of how a servlet container works, but IMHO it proves the point.
So I would make my design choice based on security consideration: will I have complete control over the code that has access to the instances? What would be the consequence of a thread's holding a lock on an instance indefinitely?
It depends on the situation.
If There is only one sharing entity or more than one.
See full working example here
A small introduction.
Threads and shareable entities
It is possible for multiple threads to access same entity, for eg multiple connectionThreads sharing a single messageQueue. Since the threads run concurrently there may be a chance of overriding one's data by another which may be a messed up situation.
So we need some way to ensure that shareable entity is accessed only by one thread at a time. (CONCURRENCY).
Synchronized block
synchronized() block is a way to ensure concurrent access of shareable entity.
First, a small analogy
Suppose There are two-person P1, P2 (threads) a Washbasin (shareable entity) inside a washroom and there is a door (lock).
Now we want one person to use washbasin at a time.
An approach is to lock the door by P1 when the door is locked P2 waits until p1 completes his work
P1 unlocks the door
then only p1 can use washbasin.
syntax.
synchronized(this)
{
SHARED_ENTITY.....
}
"this" provided the intrinsic lock associated with the class (Java developer designed Object class in such a way that each object can work as monitor).
Above approach works fine when there are only one shared entity and multiple threads (1: N).
N shareable entities-M threads
Now think of a situation when there is two washbasin inside a washroom and only one door. If we are using the previous approach, only p1 can use one washbasin at a time while p2 will wait outside. It is wastage of resource as no one is using B2 (washbasin).
A wiser approach would be to create a smaller room inside washroom and provide them one door per washbasin. In this way, P1 can access B1 and P2 can access B2 and vice-versa.
washbasin1;
washbasin2;
Object lock1=new Object();
Object lock2=new Object();
synchronized(lock1)
{
washbasin1;
}
synchronized(lock2)
{
washbasin2;
}
See more on Threads----> here
There seems a different consensus in the C# and Java camps on this. The majority of Java code I have seen uses:
// apply mutex to this instance
synchronized(this) {
// do work here
}
whereas the majority of C# code opts for the arguably safer:
// instance level lock object
private readonly object _syncObj = new object();
...
// apply mutex to private instance level field (a System.Object usually)
lock(_syncObj)
{
// do work here
}
The C# idiom is certainly safer. As mentioned previously, no malicious / accidental access to the lock can be made from outside the instance. Java code has this risk too, but it seems that the Java community has gravitated over time to the slightly less safe, but slightly more terse version.
That's not meant as a dig against Java, just a reflection of my experience working on both languages.
Make your data immutable if it is possible ( final variables)
If you can't avoid mutation of shared data across multiple threads, use high level programming constructs [e.g. granular Lock API ]
A Lock provides exclusive access to a shared resource: only one thread at a time can acquire the lock and all access to the shared resource requires that the lock be acquired first.
Sample code to use ReentrantLock which implements Lock interface
class X {
private final ReentrantLock lock = new ReentrantLock();
// ...
public void m() {
lock.lock(); // block until condition holds
try {
// ... method body
} finally {
lock.unlock()
}
}
}
Advantages of Lock over Synchronized(this)
The use of synchronized methods or statements forces all lock acquisition and release to occur in a block-structured way.
Lock implementations provide additional functionality over the use of synchronized methods and statements by providing
A non-blocking attempt to acquire a lock (tryLock())
An attempt to acquire the lock that can be interrupted (lockInterruptibly())
An attempt to acquire the lock that can timeout (tryLock(long, TimeUnit)).
A Lock class can also provide behavior and semantics that is quite different from that of the implicit monitor lock, such as
guaranteed ordering
non-re entrant usage
Deadlock detection
Have a look at this SE question regarding various type of Locks:
Synchronization vs Lock
You can achieve thread safety by using advanced concurrency API instead of Synchronied blocks. This documentation page provides good programming constructs to achieve thread safety.
Lock Objects support locking idioms that simplify many concurrent applications.
Executors define a high-level API for launching and managing threads. Executor implementations provided by java.util.concurrent provide thread pool management suitable for large-scale applications.
Concurrent Collections make it easier to manage large collections of data, and can greatly reduce the need for synchronization.
Atomic Variables have features that minimize synchronization and help avoid memory consistency errors.
ThreadLocalRandom (in JDK 7) provides efficient generation of pseudorandom numbers from multiple threads.
Refer to java.util.concurrent and java.util.concurrent.atomic packages too for other programming constructs.
The java.util.concurrent package has vastly reduced the complexity of my thread safe code. I only have anecdotal evidence to go on, but most work I have seen with synchronized(x) appears to be re-implementing a Lock, Semaphore, or Latch, but using the lower-level monitors.
With this in mind, synchronizing using any of these mechanisms is analogous to synchronizing on an internal object, rather than leaking a lock. This is beneficial in that you have absolute certainty that you control the entry into the monitor by two or more threads.
If you've decided that:
the thing you need to do is lock on
the current object; and
you want to
lock it with granularity smaller than
a whole method;
then I don't see the a taboo over synchronizezd(this).
Some people deliberately use synchronized(this) (instead of marking the method synchronized) inside the whole contents of a method because they think it's "clearer to the reader" which object is actually being synchronized on. So long as people are making an informed choice (e.g. understand that by doing so they're actually inserting extra bytecodes into the method and this could have a knock-on effect on potential optimisations), I don't particularly see a problem with this. You should always document the concurrent behaviour of your program, so I don't see the "'synchronized' publishes the behaviour" argument as being so compelling.
As to the question of which object's lock you should use, I think there's nothing wrong with synchronizing on the current object if this would be expected by the logic of what you're doing and how your class would typically be used. For example, with a collection, the object that you would logically expect to lock is generally the collection itself.
I think there is a good explanation on why each of these are vital techniques under your belt in a book called Java Concurrency In Practice by Brian Goetz. He makes one point very clear - you must use the same lock "EVERYWHERE" to protect the state of your object. Synchronised method and synchronising on an object often go hand in hand. E.g. Vector synchronises all its methods. If you have a handle to a vector object and are going to do "put if absent" then merely Vector synchronising its own individual methods isn't going to protect you from corruption of state. You need to synchronise using synchronised (vectorHandle). This will result in the SAME lock being acquired by every thread which has a handle to the vector and will protect overall state of the vector. This is called client side locking. We do know as a matter of fact vector does synchronised (this) / synchronises all its methods and hence synchronising on the object vectorHandle will result in proper synchronisation of vector objects state. Its foolish to believe that you are thread safe just because you are using a thread safe collection. This is precisely the reason ConcurrentHashMap explicitly introduced putIfAbsent method - to make such operations atomic.
In summary
Synchronising at method level allows client side locking.
If you have a private lock object - it makes client side locking impossible. This is fine if you know that your class doesn't have "put if absent" type of functionality.
If you are designing a library - then synchronising on this or synchronising the method is often wiser. Because you are rarely in a position to decide how your class is going to be used.
Had Vector used a private lock object - it would have been impossible to get "put if absent" right. The client code will never gain a handle to the private lock thus breaking the fundamental rule of using the EXACT SAME LOCK to protect its state.
Synchronising on this or synchronised methods do have a problem as others have pointed out - someone could get a lock and never release it. All other threads would keep waiting for the lock to be released.
So know what you are doing and adopt the one that's correct.
Someone argued that having a private lock object gives you better granularity - e.g. if two operations are unrelated - they could be guarded by different locks resulting in better throughput. But this i think is design smell and not code smell - if two operations are completely unrelated why are they part of the SAME class? Why should a class club unrelated functionalities at all? May be a utility class? Hmmmm - some util providing string manipulation and calendar date formatting through the same instance?? ... doesn't make any sense to me at least!!
No, you shouldn't always. However, I tend to avoid it when there are multiple concerns on a particular object that only need to be threadsafe in respect to themselves. For example, you might have a mutable data object that has "label" and "parent" fields; these need to be threadsafe, but changing one need not block the other from being written/read. (In practice I would avoid this by declaring the fields volatile and/or using java.util.concurrent's AtomicFoo wrappers).
Synchronization in general is a bit clumsy, as it slaps a big lock down rather than thinking exactly how threads might be allowed to work around each other. Using synchronized(this) is even clumsier and anti-social, as it's saying "no-one may change anything on this class while I hold the lock". How often do you actually need to do that?
I would much rather have more granular locks; even if you do want to stop everything from changing (perhaps you're serialising the object), you can just acquire all of the locks to achieve the same thing, plus it's more explicit that way. When you use synchronized(this), it's not clear exactly why you're synchronizing, or what the side effects might be. If you use synchronized(labelMonitor), or even better labelLock.getWriteLock().lock(), it's clear what you are doing and what the effects of your critical section are limited to.
Short answer: You have to understand the difference and make choice depending on the code.
Long answer: In general I would rather try to avoid synchronize(this) to reduce contention but private locks add complexity you have to be aware of. So use the right synchronization for the right job. If you are not so experienced with multi-threaded programming I would rather stick to instance locking and read up on this topic. (That said: just using synchronize(this) does not automatically make your class fully thread-safe.) This is a not an easy topic but once you get used to it, the answer whether to use synchronize(this) or not comes naturally.
A lock is used for either visibility or for protecting some data from concurrent modification which may lead to race.
When you need to just make primitive type operations to be atomic there are available options like AtomicInteger and the likes.
But suppose you have two integers which are related to each other like x and y co-ordinates, which are related to each other and should be changed in an atomic manner. Then you would protect them using a same lock.
A lock should only protect the state that is related to each other. No less and no more. If you use synchronized(this) in each method then even if the state of the class is unrelated all the threads will face contention even if updating unrelated state.
class Point{
private int x;
private int y;
public Point(int x, int y){
this.x = x;
this.y = y;
}
//mutating methods should be guarded by same lock
public synchronized void changeCoordinates(int x, int y){
this.x = x;
this.y = y;
}
}
In the above example I have only one method which mutates both x and y and not two different methods as x and y are related and if I had given two different methods for mutating x and y separately then it would not have been thread safe.
This example is just to demonstrate and not necessarily the way it should be implemented. The best way to do it would be to make it IMMUTABLE.
Now in opposition to Point example, there is an example of TwoCounters already provided by #Andreas where the state which is being protected by two different locks as the state is unrelated to each other.
The process of using different locks to protect unrelated states is called Lock Striping or Lock Splitting
The reason not to synchronize on this is that sometimes you need more than one lock (the second lock often gets removed after some additional thinking, but you still need it in the intermediate state). If you lock on this, you always have to remember which one of the two locks is this; if you lock on a private Object, the variable name tells you that.
From the reader's viewpoint, if you see locking on this, you always have to answer the two questions:
what kind of access is protected by this?
is one lock really enough, didn't someone introduce a bug?
An example:
class BadObject {
private Something mStuff;
synchronized setStuff(Something stuff) {
mStuff = stuff;
}
synchronized getStuff(Something stuff) {
return mStuff;
}
private MyListener myListener = new MyListener() {
public void onMyEvent(...) {
setStuff(...);
}
}
synchronized void longOperation(MyListener l) {
...
l.onMyEvent(...);
...
}
}
If two threads begin longOperation() on two different instances of BadObject, they acquire
their locks; when it's time to invoke l.onMyEvent(...), we have a deadlock because neither of the threads may acquire the other object's lock.
In this example we may eliminate the deadlock by using two locks, one for short operations and one for long ones.
As already said here synchronized block can use user-defined variable as lock object, when synchronized function uses only "this". And of course you can manipulate with areas of your function which should be synchronized and so on.
But everyone says that no difference between synchronized function and block which covers whole function using "this" as lock object. That is not true, difference is in byte code which will be generated in both situations. In case of synchronized block usage should be allocated local variable which holds reference to "this". And as result we will have a little bit larger size of function (not relevant if you have only few number of functions).
More detailed explanation of the difference you can find here:
http://www.artima.com/insidejvm/ed2/threadsynchP.html
Also usage of synchronized block is not good due to following point of view:
The synchronized keyword is very limited in one area: when exiting a synchronized block, all threads that are waiting for that lock must be unblocked, but only one of those threads gets to take the lock; all the others see that the lock is taken and go back to the blocked state. That's not just a lot of wasted processing cycles: often the context switch to unblock a thread also involves paging memory off the disk, and that's very, very, expensive.
For more details in this area I would recommend you read this article:
http://java.dzone.com/articles/synchronized-considered
This is really just supplementary to the other answers, but if your main objection to using private objects for locking is that it clutters your class with fields that are not related to the business logic then Project Lombok has #Synchronized to generate the boilerplate at compile-time:
#Synchronized
public int foo() {
return 0;
}
compiles to
private final Object $lock = new Object[0];
public int foo() {
synchronized($lock) {
return 0;
}
}
A good example for use synchronized(this).
// add listener
public final synchronized void addListener(IListener l) {listeners.add(l);}
// remove listener
public final synchronized void removeListener(IListener l) {listeners.remove(l);}
// routine that raise events
public void run() {
// some code here...
Set ls;
synchronized(this) {
ls = listeners.clone();
}
for (IListener l : ls) { l.processEvent(event); }
// some code here...
}
As you can see here, we use synchronize on this to easy cooperate of lengthly (possibly infinite loop of run method) with some synchronized methods there.
Of course it can be very easily rewritten with using synchronized on private field. But sometimes, when we already have some design with synchronized methods (i.e. legacy class, we derive from, synchronized(this) can be the only solution).
It depends on the task you want to do, but I wouldn't use it. Also, check if the thread-save-ness you want to accompish couldn't be done by synchronize(this) in the first place? There are also some nice locks in the API that might help you :)
I only want to mention a possible solution for unique private references in atomic parts of code without dependencies. You can use a static Hashmap with locks and a simple static method named atomic() that creates required references automatically using stack information (full class name and line number). Then you can use this method in synchronize statements without writing new lock object.
// Synchronization objects (locks)
private static HashMap<String, Object> locks = new HashMap<String, Object>();
// Simple method
private static Object atomic() {
StackTraceElement [] stack = Thread.currentThread().getStackTrace(); // get execution point
StackTraceElement exepoint = stack[2];
// creates unique key from class name and line number using execution point
String key = String.format("%s#%d", exepoint.getClassName(), exepoint.getLineNumber());
Object lock = locks.get(key); // use old or create new lock
if (lock == null) {
lock = new Object();
locks.put(key, lock);
}
return lock; // return reference to lock
}
// Synchronized code
void dosomething1() {
// start commands
synchronized (atomic()) {
// atomic commands 1
...
}
// other command
}
// Synchronized code
void dosomething2() {
// start commands
synchronized (atomic()) {
// atomic commands 2
...
}
// other command
}
Avoid using synchronized(this) as a locking mechanism: This locks the whole class instance and can cause deadlocks. In such cases, refactor the code to lock only a specific method or variable, that way whole class doesn't get locked. Synchronised can be used inside method level.
Instead of using synchronized(this), below code shows how you could just lock a method.
public void foo() {
if(operation = null) {
synchronized(foo) {
if (operation == null) {
// enter your code that this method has to handle...
}
}
}
}
My two cents in 2019 even though this question could have been settled already.
Locking on 'this' is not bad if you know what you are doing but behind the scene locking on 'this' is (which unfortunately what synchronized keyword in method definition allows).
If you actually want users of your class to be able to 'steal' your lock (i.e. prevent other threads from dealing with it), you actually want all the synchronized methods to wait while another sync method is running and so on.
It should be intentional and well thought off (and hence documented to help your users understand it).
To further elaborate, in the reverse you must know what you are 'gaining' (or 'losing' out on) if you lock on a non accessible lock (nobody can 'steal' your lock, you are in total control and so on...).
The problem for me is that synchronized keyword in the method definition signature makes it just too easy for programmers not to think about what to lock on which is a mighty important thing to think about if you don't want to run into problems in a multi-threaded program.
One can't argue that 'typically' you don't want users of your class to be able to do these stuff or that 'typically' you want...It depends on what functionality you are coding. You can't make a thumb rule as you can't predict all the use cases.
Consider for e.g. the printwriter which uses an internal lock but then people struggle to use it from multiple threads if they don't want their output to interleave.
Should your lock be accessible outside of the class or not is your decision as a programmer on the basis of what functionality the class has. It is part of the api. You can't move away for instance from synchronized(this) to synchronized(provateObjet) without risking breaking changes in the code using it.
Note 1: I know you can achieve whatever synchronized(this) 'achieves' by using a explicit lock object and exposing it but I think it is unnecessary if your behaviour is well documented and you actually know what locking on 'this' means.
Note 2: I don't concur with the argument that if some code is accidentally stealing your lock its a bug and you have to solve it. This in a way is same argument as saying I can make all my methods public even if they are not meant to be public. If someone is 'accidentally' calling my intended to be private method its a bug. Why enable this accident in the first place!!! If ability to steal your lock is a problem for your class don't allow it. As simple as that.
Let me put the conclusion first - locking on private fields does not work for slightly more complicated multi-threaded program. This is because multi-threading is a global problem. It is impossible to localize synchronization unless you write in a very defensive way (e.g. copy everything on passing to other threads).
Here is the long explanation:
Synchronization includes 3 parts: Atomicity, Visibility and Ordering
Synchronized block is very coarse level of synchronization. It enforces visibility and ordering just as what you expected. But for atomicity, it does not provide much protection. Atomicity requires global knowledge of the program rather than local knowledge. (And that makes multi-threading programming very hard)
Let's say we have a class Account having method deposit and withdraw. They are both synchronized based on a private lock like this:
class Account {
private Object lock = new Object();
void withdraw(int amount) {
synchronized(lock) {
// ...
}
}
void deposit(int amount) {
synchronized(lock) {
// ...
}
}
}
Considering we need to implement a higher-level class which handles transfer, like this:
class AccountManager {
void transfer(Account fromAcc, Account toAcc, int amount) {
if (fromAcc.getBalance() > amount) {
fromAcc.setBalance(fromAcc.getBalance() - amount);
toAcc.setBalance(toAcc.getBalance + amount);
}
}
}
Assuming we have 2 accounts now,
Account john;
Account marry;
If the Account.deposit() and Account.withdraw() are locked with internal lock only. That will cause problem when we have 2 threads working:
// Some thread
void threadA() {
john.withdraw(500);
}
// Another thread
void threadB() {
accountManager.transfer(john, marry, 100);
}
Because it is possible for both threadA and threadB run at the same time. And thread B finishes the conditional check, thread A withdraws, and thread B withdraws again. This means we can withdraw $100 from John even if his account has no enough money. This will break atomicity.
You may propose that: why not adding withdraw() and deposit() to AccountManager then? But under this proposal, we need to create a multi-thread safe Map which maps from different accounts to their locks. We need to delete the lock after execution (otherwise will leak memory). And we also need to ensure no other one accesses the Account.withdraw() directly. This will introduce a lots of subtle bugs.
The correct and most idiomatic way is to expose the lock in the Account. And let the AccountManager to use the lock. But in this case, why not just use the object itself then?
class Account {
synchronized void withdraw(int amount) {
// ...
}
synchronized void deposit(int amount) {
// ...
}
}
class AccountManager {
void transfer(Account fromAcc, Account toAcc, int amount) {
// Ensure locking order to prevent deadlock
Account firstLock = fromAcc.hashCode() < toAcc.hashCode() ? fromAcc : toAcc;
Account secondLock = fromAcc.hashCode() < toAcc.hashCode() ? toAcc : fromAcc;
synchronized(firstLock) {
synchronized(secondLock) {
if (fromAcc.getBalance() > amount) {
fromAcc.setBalance(fromAcc.getBalance() - amount);
toAcc.setBalance(toAcc.getBalance + amount);
}
}
}
}
}
To conclude in simple English, private lock does not work for slightly more complicated multi-threaded program.
(Reposted from https://stackoverflow.com/a/67877650/474197)
I think points one (somebody else using your lock) and two (all methods using the same lock needlessly) can happen in any fairly large application. Especially when there's no good communication between developers.
It's not cast in stone, it's mostly an issue of good practice and preventing errors.