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My question is related to multithreading lock-free synchronization. I wanted to know the following:

  1. What are general approaches to achieve this? I read somewhere about LockFreePrimitives like CompareAndExchange (CAS) or DoubleCompareAndExchange (DCA) but no explanation for those were given? Any approaches to MINIMIZE use of locks?

  2. How does Java/.NET achieve their concurrent containers? Do they use locks or lock-free synch?

Thanks in advance.

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3 Answers

up vote 4 down vote accepted

Here are some general approaches that can minimize the use of locks, assuming your algorithm fulfills has some particular exploitable features:

  1. When updating a single numeric variable, you can use non-blocking primitives such as CAS, atomic_increment, etc. They are usually much faster that a classic blocking critical section (lock, mutex).

  2. When a data structure is read by multiple threads, but only written by one or few threads, an obvious solution would be a read-write lock, instead of a full lock.

  3. Try to exploit fine grain locking. For example, instead of locking an entire data structure with a single lock, see if you can use multiple different locks to protect distinct sections of the data structure.

  4. If you're relying on the implicit memory fence effect of locks to ensure visibility of a single variable across threads, just use volatile, if available.

  5. Sometimes, using a conditional variable (and associated lock) is too slow in practice. In this case, a volatile busy spin is much more efficient.

More good advice on this topic here: http://software.intel.com/en-us/articles/intel-guide-for-developing-multithreaded-applications/

A nice read in another SO question: Lock-free multi-threading is for real threading experts (don't be scared by the title).

And a recently discussed lock-free Java implementation of atomic_decrement: Starvation in non-blocking approaches

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You have some good point, but #4 is wrong. volatile doesn't do what you expect it to do. It may prevent the compiler from doing some optimizations, but doesn't prevent the processor from reordering reads, and therefore can't replace a barrier. –  ugoren Feb 1 '12 at 22:16
    
@ugoren That is incorrect in Java context. A volatile read/store deploys necessary memory barriers. –  John Vint Feb 1 '12 at 22:24
    
@JohnVint, I admit I don't know much about Java, and was thinking about C (where volatile is the most misunderstood keyword). Since the question isn't tagged "Java", this should at least be made clear. –  ugoren Feb 1 '12 at 22:42
    
@ugoren You're right it isnt tagged in Java. If Tudor was talking about Java when referencing volatile he should include that. –  John Vint Feb 1 '12 at 22:47
    
Well, in the original question he was asking about lock-free collections in Java/C#, so my answer applies (mainly) to these languages. –  Tudor Feb 1 '12 at 22:58
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There are some useful way to use lock-free sychronization (such as those @Tudor mentions). But I want to warn about one thing - lock-free syncrhonization doesn't compose.

You may have, for example, an integer maintained by compare&swap, and it's OK. You may also have a queue, maintained by a lock-free algorithms (it's a bit tricky, but there are good algorithms for it), and the queue is also OK.
But if you try to use the counter to count the elements in a queue, you'll get wrong answers. There will be times when an element was added, but the counter doesn't yet reflect it (or vice versa), and you can get bugs if you trust it (e.g. you may try to add to a full queue).

In short - you can have each element consistent with itself, but not consistent with each other.

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Compare and swap is useful, but there is an even simpler (so called 'lock-free') technique that is useful in certain producer/consumer use cases that might be useful so I will mention it.

Imagine you have a function doWork() that writes to a buffer.

  1. Thread A initializes a volatile boolean variable (flag) to false that is accessible by both Thread A and creates a volatile buffer object that doWork will output to Thread B (Global, etc).
  2. Thread A creates thread B, which calls doWork().
  3. Thread B's doWork() begins creating/writing to the buffer. When finished, it sets the boolean to true.
  4. Thread A can poll a global boolean flag that starts out false. When it turns true (non false), it can access the data in the buffer object, assured that is finished. Between polls Thread A can do other work. (So for example it polls once in an update call and does not wait for a true value). This doesn't take into account error handling, but this can also be handled within the buffer.

This only works because A only reads and B only writes, but this use case is fairly common for 'background worker' threads. This will only sure to work on Java or C# where volatile comes with the guarantees.

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You can't use a simple Boolean for such synchronization. The compiler and/or processor may reorder your reads, leading to bugs. You think you read the Boolean first (and see that it's true), and only then read the buffer. But in reality (an you get "half baked" data), the reads may be reversed. You need a semaphore. –  ugoren Feb 1 '12 at 22:14
    
I believe there will never be a case where thread A reads the and uses the buffer first, because it is read within a conditional dependent on value the boolean read, and the compiler will not switch this stuff around. This is why you can write a conditional that checks null pointers and then use the pointer after that. –  Michael Chinen Feb 1 '12 at 22:22
    
I'm not against believing in principle, but in multi-threaded programming, it's a big mistake. The compiler may or may not switch stuff around, but the CPU may, when different addresses are involved. Intel CPUs do quite a lot of reordering, and I've already seen amazing bugs due to it. –  ugoren Feb 1 '12 at 22:40
    
Again, compiler reordering obeys certain rules, and this technique abides by them. Besides belief I explained the conditional case which compilers respect. –  Michael Chinen Feb 1 '12 at 22:52
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You're ignoring out-of-order execution. Suppose the compiler did all you expect, and you have machine code such as mov var1,%eax; test %eax,%eax; jz somewhere; mov var2,%eax. Reading var2 is done after var1 was read and verified to be non-zero. But the CPU can still reorder, and read var2 first, var1 later (maybe because var2 was in a nearer cache). If var1 ends up 0, the var2 value is discarded. But if it ends up non-zero, the old value will be used. –  ugoren Feb 2 '12 at 7:53
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