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When objects are locked in languages like C++ and Java where actually on a low level scale) is this performed? I don't think it's anything to do with the CPU/cache or RAM. My best guestimate is that this occurs somewhere in the OS? Would it be within the same part of the OS which performs context switching?

I am referring to locking objects, synchronizing on method signatures (Java) etc.

It could be that the answer depends on which particular locking mechanism?

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You should really split this into two questions, one about Java and one about C++. They are completely different languages. – Crazy Eddie May 8 '12 at 22:35
AFAIK atomics in C++ match CPU instructions while the actual locks call OS libraries like pthread. – Pubby May 8 '12 at 22:36
Have a look at this article for very low level stuff (with java examples). – assylias May 8 '12 at 22:53
up vote 4 down vote accepted

Locking involves a synchronisation primitive, typically a mutex. While naively speaking a mutex is just a boolean flag that says "locked" or "unlocked", the devil is in the detail: The mutex value has to be read, compared and set atomically, so that multiple threads trying for the same mutex don't corrupt its state.

But apart from that, instructions have to be ordered properly so that the effects of a read and write of the mutex variable are visible to the program in the correct order and that no thread inadvertently enters the critical section when it shouldn't because it failed to see the lock update in time.

There are two aspects to memory access ordering: One is done by the compiler, which may choose to reorder statements if that's deemed more efficient. This is relatively trivial to prevent, since the compiler knows when it must be careful. The far more difficult phenomenon is that the CPU itself, internally, may choose to reorder instructions, and it must be prevented from doing so when a mutex variable is being accessed for the purpose of locking. This requires hardware support (e.g. a "lock bit" which causes a pipeline flush and a bus lock).

Finally, if you have multiple physical CPUs, each CPU will have its own cache, and it becomes important that state updates are propagated to all CPU caches before any executing instructions make further progress. This again requires dedicated hardware support.

As you can see, synchronisation is a (potentially) expensive business that really gets in the way of concurrent processing. That, however, is simply the price you pay for having one single block of memory on which multiple independent context perform work.

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There is no concept of object locking in C++. You will typically implement your own on top of OS-specific functions or use synchronization primitives provided by libraries (e.g. boost::scoped_lock). If you have access to C++11, you can use the locks provided by the threading library which has a similar interface to boost, take a look.

In Java the same is done for you by the JVM.

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Well, that was true in 2003... – Kerrek SB May 8 '12 at 22:32
Added some C++11 info. :) – Klemens Baum May 8 '12 at 22:35
boost mimics the standard here, not the other way around ;) – Crazy Eddie May 8 '12 at 22:35
Didn't even realize that, probably because boost is so much faster at implementing these things than stdlib vendors. – Klemens Baum May 8 '12 at 22:38
The history: first there was boost.thread. Then the standard committee used it to design the C++11 standard. Boost.thread was then redone to mimic this design. It did make it out to the public like 5 years or something. Boost.thread is not quite std::thread, but it gets as close as can be done. – Crazy Eddie May 8 '12 at 22:51

The java.lang.Object has a monitor built into it. That's what is used to lock for the synchronized keyword. JDK 6 added a concurrency packages that give you more fine-grained choices.

This has a nice explanation:

I haven't written C++ in a long time, so I can't speak to how to do it in that language. It wasn't supported by the language when I last wrote it. I believe it was all 3rd party libraries or custom code.

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@Java, ok but what "actually" is the monitor? Is it a register on the CPU etc? :) – user997112 May 8 '12 at 23:12

It does depend on the particular locking mechanism, typically a semaphore, but you cannot be sure, since it is implementation dependent.

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All architectures I know of use an atomic Compare And Swap to implement their synchronization primitives. See, for example, AbstractQueuedSynchronizer, which was used in some JDK versions to implement Semiphore and ReentrantLock.

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