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I wrote a simple lockless queue based off of the principles outlined in the msdn article below, and from the DXUT lock free pipe code also below:

So, I have a producer/consumer model setup where my main thread feeds rendering instructions, and an rendering thread consumes available messages and issues the corresponding opengl calls. Things work fine if I sleep my main thread each loop/iteration for a sufficient amount of time, but if I don't sleep it long enough (or not at all), I get an access violation exception:

First-chance exception at 0x00b28d9c in Engine.exe: 0xC0000005: Access violation reading location 0x00004104.
Unhandled exception at 0x777715ee in Engine.exe: 0xC0000005: Access violation reading location 0x00004104.

My call stack is:

[Frames below may be incorrect and/or missing, no symbols loaded for ntdll.dll] 
Engine.exe!RingBuffer<2048>::BeginRead(void * & ppMem=, unsigned long & BytesAvailable=)  Line 52 + 0x10 bytes  C++
Engine.exe!Thread::ThreadMain(void * lpParam=0x00107d94)  Line 41 + 0xf bytes   C++

I can't quite figure out what the problem might be. The Code for my lockless queue is below:

    template <uint32 BufferSize>
    class RingBuffer
            : m_ReadOffset(0)
            , m_WriteOffset(0)

        bool Empty() const
            return (m_WriteOffset == m_ReadOffset);

        void BeginRead(void*& ppMem, uint32& BytesAvailable)
            const uint32 ReadOffset = m_ReadOffset;
            const uint32 WriteOffset = m_WriteOffset;


            const uint32 Slack =    (WriteOffset > ReadOffset) ?
                            (WriteOffset - ReadOffset) :
                            (ReadOffset > WriteOffset) ?
                                (c_BufferSize - ReadOffset) :

            ppMem = (m_Buffer + ReadOffset);
            BytesAvailable = Slack;

        void EndRead(const uint32 BytesRead)
            uint32 ReadOffset = m_ReadOffset;


            ReadOffset += BytesRead;
            ReadOffset %= c_BufferSize;

            m_ReadOffset = ReadOffset;

        void BeginWrite(void*& ppMem, uint32& BytesAvailable)
            const uint32 ReadOffset = m_ReadOffset;
            const uint32 WriteOffset = m_WriteOffset;


            const uint32 Slack =    (WriteOffset > ReadOffset || WriteOffset == ReadOffset) ?
                            (c_BufferSize - WriteOffset) :
                            (ReadOffset - WriteOffset);

            ppMem = (m_Buffer + WriteOffset);
            BytesAvailable = Slack;

        void EndWrite(const uint32 BytesWritten)
            uint32 WriteOffset = m_WriteOffset;


            WriteOffset += BytesWritten;
            WriteOffset %= c_BufferSize;

            m_WriteOffset = WriteOffset;

        const static uint32 c_BufferSize = NEXT_POWER_OF_2(BufferSize);
        const static uint32 c_SizeMask = c_BufferSize - 1;

        byte8 m_Buffer[ c_BufferSize ];
        volatile ALIGNMENT(4) uint32 m_ReadOffset;
        volatile ALIGNMENT(4) uint32 m_WriteOffset;

I'm having difficulty debugging it as the read/write offsets and buffer pointer look fine from the watch window. Unfortunately, when the app breaks, I can't watch autos/local variables from the BeginRead function. If anyone has experience working with lockless programming, any help on this problem or advice in general would be greatly appreaciated.

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Just as an observation, your data structure doesn't seem to contain any atomic variables or atomic operations - how is this going to work? –  Kerrek SB Aug 7 '11 at 23:15
I was under the impression that read/writes to m_ReadOffset and m_WriteOffset would be atomic given the alignment and their size. Is that not the case? –  programmer Aug 7 '11 at 23:51
@programmer It's not necessarily the case that reads and writes would be consistent between CPUs. –  msandiford Aug 7 '11 at 23:53
Hm, that's fishy. Even if reads and writes were atomic, you're making no attempt to verify that the structure is still in the correct state when you write the update. I believe something like an atomic compare-and-swap would be an inevitable part of a concurrent container. –  Kerrek SB Aug 7 '11 at 23:56
Was there something wrong with the standardized types such as uint32_t? –  Ben Voigt Aug 7 '11 at 23:58

2 Answers 2

You might find these articles of some interest...

Lock-Free Code: A False Sense of Security
Writing Lock-Free Code: A Corrected Queue

In the first article Herb Sutter discusses another author's implementation of a lock-free queue and points out some of the things that can go wrong. In the second article Herb shows some corrections to the original implementation.

As a learning exercise, trying to build your own lock-free queue is a pretty good idea. But for production work you'd probably be safer finding a pre-existing implementation from a reliable source and using that. For example, the Concurrency Runtime offers the concurrent_queue class

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You haven't any memory fences. Access to volatile variables are only ordered with respect to each other, not to other operations.

In C++0x, you'll be able to use std::atomic<T> to get the appropriate fences. Until then you'll need OS-specific threading APIs, such as Win32 InterlockedExchange, or a wrapper library such as boost::thread.

Ok, I see that AppReadWriteBarrier is supposed to provide a memory fence. How's it implemented?

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The function AppReadWriteBarrier is a wrapper on win32 for _ReadWriteBarrier, which serves as a memory fence I believe? –  programmer Aug 7 '11 at 23:59
@programmer: You'd think so, but the MSDN page makes it sound weaker. What compiler version are you using? –  Ben Voigt Aug 8 '11 at 0:01
@Programmer: Pay special attention to the caution on top of the documentation page. –  Ben Voigt Aug 8 '11 at 0:03
Oh, I missed that part of the doc! I'm using Visual Studio 2008, v 9.0.21022.8 –  programmer Aug 8 '11 at 0:04
Hmmm. The documentation here says that VS 2005 uses lfence/sfence for volatile access on SSE2 in any case (not 100% sure if this applies to VS 2008): msdn.microsoft.com/en-us/library/ms686355(v=vs.85).aspx –  msandiford Aug 8 '11 at 0:12

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