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I'm currently in the process of developing my own little threading library, mainly for learning purposes, and am at the part of the message queue which will involve a lot of synchronisation in various places. Previously I've mainly used locks, mutexes and condition variables a bit which all are variations of the same theme, a lock for a section that should only be used by one thread at a time.

Are there any different solutions to synchronisation than using locks? I've read lock-free synchronization at places, but some consider hiding the locks in containers to be lock-free, which I disagree with. you just don't explicitly use the locks yourself.

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4 Answers 4

up vote 11 down vote accepted

Lock-free algorithms typically involve using compare-and-swap (CAS) or similar instructions that update some value in memory not only atomically, but also conditionally and with an indicator of success. That way you can code something like this:

do
{
    read the current value
    calculate the new value
} while(!compare_and_swap(current_value, new_value);
  • exact calling syntax will vary with the CPU, and may involve assembly language or system/compiler-provided wrapper functions
    • use provided wrappers if available - there may be other compiler optimisations or issues that their usage restricts to safe behaviours, otherwise check your docs

The significance is that when there's a race, the compare and swap instruction will fail because the state from which you're updating is not the one you used to calculate the desired target state. Such instructions can be said to "spin" rather than lock, as they go round and round the loop until spat out successfully.

Crucially, your existing threading library may well have a two-stage locking approach for mutex, read-write locks etc. involving spinning using CAS or similar (i.e. spin on { read the current value, if it's not set then cas(current = not set, new = set) }) - which means other threads doing a quick update often won't result in your thread swapping out to wait, and all the relatively time-consuming overheads associated with that. The second stage will be to tell the operating system to queue the thread until it finds the mutex free. The implication of this is that if you're using a mutex to protect access to a variable, then you are unlikely to do any better by implementing your own "mutex" to protect the same variable.

Lock free algorithms come into their own when you are working directly on a variable that's small enough to update directly with the CAS instruction itself. Instead of being...

  • get a mutex (by spinning on CAS, falling back on slower OS queue)
  • update variable
  • release mutex

...they're simplified (and made faster) by simply having the spin on CAS. Of course, you may find the work to calculate new value from old painful to repeat speculatively, but unless there's a LOT of contention you're not doing that often.

This ability to update only a single location in memory has far-reaching implications, and work-arounds can require some creativity. For example, if you had a container using lock-free algorithms, you may decide to calculate a potential change to an element in the container, but can't sync that with updating a size variable elsewhere in memory. You may need to live without size, or be able to use an approximate size where you do a CAS-spin to increment or decrement the size later, but any given read may be slightly wrong. You may need to merge two logically-related data structures - such as a free list and the element-container - to share an index, then bit-pack the core fields for each into the same atomically-sized word at the start of each record. These kinds of data optimisations can be very invasive, and sometimes won't get you the behavioural characteristics you'd like. Mutexes et al are much easier in this regard, and at least you know you won't need a rewrite to mutexes if requirements evolve just that step too far. That said, clever use of a lock-free approach really can be adequate for a lot of needs, and yield a very gratifying performance and scalability improvement.

A core (good) consequence of lock-free algorithms is that one thread can't be holding the mutex then happen to get swapped out by the scheduler, such that other threads can't work until it resumes; rather - with CAS - they can spin safely and efficiently without an OS fallback option.

Things that lock free algorithms can be good for include updating usage/reference counters, modifying pointers to cleanly switch the pointed-to data, free lists, linked lists, marking hash-table buckets used/unused, and load-balancing. Many others of course.

As you say, simply hiding use of mutexes behind some API is not lock free.

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What does CAS stand for in this case? I tried googling for it but three letter abbreviations abound. –  dutt Nov 26 '10 at 5:37
    
Compare-And-Swap (en.wikipedia.org/wiki/Compare-and-swap). "CAS" is the assembly language keyword used on the Sun UltraSparc CPUs. "CMPXCHG" in analogous on Intel/AMDs etc. –  Tony D Nov 26 '10 at 5:43
1  
+1 for an excellent description for some of the designs that are based on lock free implementations. –  Billy ONeal Nov 26 '10 at 5:53
    
Ah, thanks for the clarification. –  dutt Nov 26 '10 at 7:05

There are a lot of different approaches to synchronization. There are various variants of message-passing (for example, CSP) or transactional memory.

Both of these may be implemented using locks, but that's an implementation detail.

And then of course, for some purposes, there are lock-free algorithms or data-structures, which make do with just a few atomic instructions (such as compare-and-swap), but this isn't really a general-purpose replacement for locks.

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There are several implementations of some data structures, which can be implemented in a lock free configuration. For example, the producer/consumer pattern can often be implemented using lock-free linked list structures.

However, most lock-free solutions require significant thought on the part of the person designing the specific program/specific problem domain. They aren't generally applicable for all problems. For examples of such implementations, take a look at Intel's Threading Building Blocks library.

Most important to note is that no lock-free solution is free. You're going to give something up to make that work, at the bare minimum in implementation complexity, and probably performance in scenarios where you're running on a single core (for example, a linked list is MUCH slower than a vector). Make sure you benchmark before using lock free on the base assumption that it would be faster.

Side note: I really hope you're not using condition variables, because there's no way to ensure that their access operates as you wish in C and C++.

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2  
Care to explain the side note? I don't get it. –  André Caron Nov 26 '10 at 5:30
    
I used the condition variables without problems in Python but like André I'm curious to know why they wouldn't operate in the same, problem-free, way. –  dutt Nov 26 '10 at 5:36
    
@Dutt: At least you'd have to have some form of platform specific use of that variable. Even using things like volatile, you need to use things like memory barriers to ensure things operate correctly on multiprocessor systems (i.e. you need an atomic compare and exchange to correctly use that kind of thing). And if you do use such things, than it's little different from an operating system lock. –  Billy ONeal Nov 26 '10 at 5:44

Yet another library to add to your reading list: Fast Flow

What's interesting in your case is that they are based on lock-free queues. They have implemented a simple lock-free queue and then have built more complex queues out of it.

And since the code is free, you can peruse it and get the code for the lock-free queue, which is far from trivial to get right.

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