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Consider the following scenario:


  • Intel x64 Server (multiple CPU-sockets => NUMA)
  • Ubuntu 12, GCC 4.6
  • Two processes sharing large amounts of data over (named) shared-memory
  • Classical producer-consumer scenario
  • Memory is arranged in a circular buffer (with M elements)

Program sequence (pseudo code):

Process A (Producer):

int bufferPos = 0;
while( true )
    if( isBufferEmpty( bufferPos ) )
        writeData( bufferPos );
        setBufferFull( bufferPos );

        bufferPos = ( bufferPos + 1 ) % M;

Process B (Consumer):

int bufferPos = 0;
while( true )
    if( isBufferFull( bufferPos ) )
        readData( bufferPos );
        setBufferEmpty( bufferPos );

        bufferPos = ( bufferPos + 1 ) % M;

Now the age-old question: How to synchronize them effectively!?

  1. Protect every read/write access with mutexes
  2. Introduce a "grace period", to allow writes to complete: Read data in buffer N, when buffer(N+3) has been marked as full (dangerous, but seems to work...)
  3. ?!?

Ideally I would like something along the lines of a memory-barrier, that guarantees that all previous reads/writes are visible across all CPUs, along the lines of:

writeData( i );

//All data written and visible, set flag
setBufferFull( i );

This way, I would only have to monitor the buffer flags and then could read the large data chunks safely.

Generally I'm looking for something along the lines of acquire/release fences as described by Preshing here:


(if I understand it correctly the C++11 atomics only work for threads of a single process and not along multiple processes.)

However the GCC-own memory barriers (__sync_synchronize in combination with the compiler barrier asm volatile( "" ::: "memory" ) to be sure) don't seem to work as expected, as writes become visible after the barrier, when I expected them to be completed.

Any help would be appreciated...

BTW: Under windows this just works fine using volatile variables (a Microsoft specific behaviour)...

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1 Answer 1

up vote 6 down vote accepted

Boost Interprocess has support for Shared Memory.

Boost Lockfree has a Single-Producer Single-Consumer queue type (spsc_queue). This is basically what you refer to as a circular buffer.

Here's a demonstration that passes IPC messages (in this case, of type string) using this queue, in a lock-free fashion.

Defining the types

First, let's define our types:

namespace bip = boost::interprocess;
namespace shm
    template <typename T>
        using alloc = bip::allocator<T, bip::managed_shared_memory::segment_manager>;

    using char_alloc    =  alloc<char>;
    using shared_string =  bip::basic_string<char, std::char_traits<char>, char_alloc >;
    using string_alloc  =  alloc<shared_string>;

    using ring_buffer = boost::lockfree::spsc_queue<
        // alternatively, pass
        // boost::lockfree::allocator<string_alloc>

For simplicity I chose to demo the runtime-size spsc_queue implementation, randomly requesting a capacity of 200 elements.

The shared_string typedef defines a string that will transparently allocate from the shared memory segment, so they are also "magically" shared with the other process.

The consumer side

This is the simplest, so:

int main()
    // create segment and corresponding allocator
    bip::managed_shared_memory segment(bip::open_or_create, "MySharedMemory", 65536);
    shm::string_alloc char_alloc(segment.get_segment_manager());

    shm::ring_buffer *queue = segment.find_or_construct<shm::ring_buffer>("queue")();

This opens the shared memory area, locates the shared queue if it exists. NOTE This should be synchronized in real life.

Now for the actual demonstration:

while (true)

    shm::shared_string v(char_alloc);
    if (queue->pop(v))
        std::cout << "Processed: '" << v << "'\n";

The consumer just infinitely monitors the queue for pending jobs and processes one each ~10ms.

The Producer side

The producer side is very similar:

int main()
    bip::managed_shared_memory segment(bip::open_or_create, "MySharedMemory", 65536);
    shm::char_alloc char_alloc(segment.get_segment_manager());

    shm::ring_buffer *queue = segment.find_or_construct<shm::ring_buffer>("queue")();

Again, add proper synchronization to the initialization phase. Also, you would probably make the producer in charge of freeing the shared memory segment in due time. In this demonstration, I just "let it hang". This is nice for testing, see below.

So, what does the producer do?

    for (const char* s : { "hello world", "the answer is 42", "where is your towel" })
        queue->push({s, char_alloc});

Right, the producer produces precisely 3 messages in ~750ms and then exits.

Note that consequently if we do (assume a POSIX shell with job control):

./producer& ./producer& ./producer&


Will print 3x3 messages "immediately", while leaving the consumer running. Doing

./producer& ./producer& ./producer&

again after this, will show the messages "trickle in" in realtime (in burst of 3 at ~250ms intervals) because the consumer is still running in the background

See the full code online in this gist: https://gist.github.com/sehe/9376856

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Just noticed gcc 4.6 mentioned. It's possible that this version doesn't have uniform inializers. Just explicitly call the constructor for shared_string then when pushing onto the queue. –  sehe Mar 5 '14 at 21:24
Thank you for your detailed answer. It is always fascinating to see how even complex problems come down to 100 lines of code in boost ;-) However my question still remains. Is there a construct of some kind that enforces memory visibility (something similar to smp_mb(), that is only available in the kernel)). Or in other words, how do mutexes enforce memory visibility? –  Ben Mar 5 '14 at 21:44
@Ben It's 54 lines of code (not counting makefile). I've just pushed a c++03 update to the gist. The Lockfree library uses atomics in the underlying implementation, so I trust it to employ the right barriers. I would be surprised if the fact that memory pages are shared has any impact on the visibility semantics. Here's some notes about Interprocess support in Boost Lockfree documentation –  sehe Mar 5 '14 at 21:49
If you're looking for a shared mutex (named mutex on Win32), see Mutex or Synchronization mechanisms overview in the Boost Interprocess docs. –  sehe Mar 5 '14 at 21:51
Ok, thank you again for your answer. I did take a look into the boost interprocess and atomics sources and only encountered "familiar" barrier implementations. So I still don't understand why the memory barrier (__sync_synchronize) does not work as expected in my implementation. However, as this goes beyond my original question, I will mark your (excellent) answer as accepted :-) –  Ben Mar 6 '14 at 9:11

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