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i have some questions in boost spinlock code :

class spinlock
        : v_(0)

    bool try_lock()
        long r = InterlockedExchange(&v_, 1);
        _ReadWriteBarrier();        // 1. what this mean            
        return r == 0;

    void lock()
        for (unsigned k = 0; !try_lock(); ++k)

    void unlock()

        *const_cast<long volatile*>(&v_) = 0;  
        // 2. Why don't need to use InterlockedExchange(&v_, 0);

    long v_;
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Well, unlocking is unconditional... –  Kerrek SB Feb 18 '13 at 9:17
@KerrekSB Also, a priori, if you're calling unlock, you have the lock, and v_ can only be 1. –  James Kanze Feb 18 '13 at 9:18

3 Answers 3

up vote 1 down vote accepted
  1. A ReadWriteBarrier() is a "memory barrier" (in this case for both reads and writes), a special instruction to the processor to ensure that any instructions resulting in memory operations have completed (load & store operations - or in for example x86 processors, any opertion which has a memory operand at either side). In this particular case, to make sure that the InterlockedExchange(&v_,1) has completed before we continue.

  2. Because an InterlockedExchange would be less efficient (takes more interaction with any other cores in the machine to ensure all other processor cores have 'let go' of the value - which makes no sense, since most likely (in correctly working code) we only unlock if we actually hold the lock, so no other processor will have a different value cached than what we're writing over anyway), and a volatile write to the memory will be just as good.

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I thought InterlockedExchange was a full read/write barrier? –  ronag Feb 18 '13 at 9:20
Since you mention x86 -- isn't x86 strongly ordered, so the memory barrier is implicit? I believe the code mainly acts as a compiler barrier on x86, with no additional machine code. –  Kerrek SB Feb 18 '13 at 9:21
It is not clear to me if it actually results in an instruction or not: msdn.microsoft.com/en-us/library/f20w0x5e%28v=vs.80%29.aspx –  Mats Petersson Feb 18 '13 at 9:23
Whether a volitile write will work depends on the compiler. It won't work with g++, for example, nor with some versions of VC++. And of course, unless the code does a yield, the other thread may not be able to read it even if it worked. –  James Kanze Feb 18 '13 at 9:50

The barriers are there to ensure memory synchronization; without them, different threads may see modifications of memory in different orders.

And the InterlockedExchange isn't necessary in the second case because we're not interested in the previous value. The role of InterlockedExchange is doubtlessly to set the value and return the previous value. (And why v_ would be long, when it can only take values 0 and 1, is beyond me.)

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What if InterlockedExchange only exists for longs? –  Kerrek SB Feb 18 '13 at 9:18
Then the author of the library isn't very good. In fact, I would expect the contrary: InterlockedExchange needs a type which it can access atomically. On a lot of platforms I've worked on, long cannot be accessed atomically. (On some, nothing larger than char could be accessed atomically.) –  James Kanze Feb 18 '13 at 9:48
This is Windows, right? I don't know it very well, but I assume they would have chosen a type (probably called LONG or ZKLNGSZINT or something handy) that is atomic. –  Kerrek SB Feb 18 '13 at 9:59
Is it Windows? If it's platform specific code, you could be right (although seriously, for a variable that can only take values 0 and 1, and has to be atomic, would you chose anything other than char or unsigned char?). –  James Kanze Feb 18 '13 at 10:26
It would seem so.. So I don't think you have a choice in that matter: The only function you can use requires a machine word operand... (you're passing a pointer!). –  Kerrek SB Feb 18 '13 at 11:51

There are three issues with atomic access to variables. First, ensuring that there is no thread switch in the middle of reading or writing a value; if this happens it's called "tearing"; the second thread can see a partly written value, which will usually be nonsensical. Second, ensuring that all processors see the change that is being made with a write, or that the processor reading a value sees any previous changes to that value; this is called "cache coherency". Third, ensuring that the compiler doesn't move code across the read or write; this is called "code motion". InterlockedExchange does the first two; although the MSDN documentation is rather muddled, _ReadWriteBarrier does the third, and possibly the second.

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