I am looking for a method to implement lock-free queue data structure that supports single producer, and multiple consumers. I have looked at the classic method by Maged Michael and Michael Scott (1996) but their version uses linked lists. I would like an implementation that makes use of bounded circular buffer. Something that uses atomic variables?

On a side note, I am not sure why these classic methods are designed for linked lists that require a lot of dynamic memory management. In a multi-threaded program, all memory management routines are serialized. Aren't we defeating the benefits of lock-free methods by using them in conjunction with dynamic data structures?

I am trying to code this in C/C++ using pthread library on a Intel 64-bit architecture.

Thank you, Shirish

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    Limited-size buffer means that producer may fail if there's no empty space in it. Is that acceptable for you? – doublep Apr 23 '10 at 22:38
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    Also note that in C++ you can supply your own allocator to std::list. Since you only have one producer, this allocator doesn't need to be synchronized. For instance, it can "allocate" list nodes from a pre-allocated buffer and, when runs out of space, allocate a new buffer with global synchronized malloc()-like "real" allocator. Which means it will use synchronization in say 1% of calls only. – doublep Apr 23 '10 at 22:41
  • tcmalloc is a great library to look at if you're looking to optimize memory-usage for threads. Since it maintains memory pools for each thread, it probably avoids the memory routine serialization problem. – Jonathan M Davis Apr 23 '10 at 22:49
  • According to my research, Intel TBBMalloc scales better than Google TCMalloc. You also can supply own allocator or use Intel TBB cache_aligned_allocator<T> to pass to std::list or std::queue – Viet Apr 24 '10 at 0:45
  • There are malloc implementations that are lock-free and mostly lock-free, along with any number of threading-aware mallocs that can avoid locking in many circumstances. – DrPizza Apr 24 '10 at 2:52

The use of a circular buffer makes a lock necessary, since blocking is needed to prevent the head from going past the tail. But otherwise the head and tail pointers can easily be updated atomically. Or in some cases the buffer can be so large that overwriting is not an issue. (in real life you will see this in automated trading systems, with circular buffers sized to hold X minutes of market data. If you are X minutes behind, you have wayyyy worse problems than overwriting your buffer).

When I implemented the MS queue in C++, I built a lock free allocator using a stack, which is very easy to implement. If I have MSQueue then at compile time I know sizeof(MSQueue::node). Then I make a stack of N buffers of the required size. The N can grow, i.e. if pop() returns null, it is easy to go ask the heap for more blocks, and these are pushed onto the stack. Outside of the possibly blocking call for more memory, this is a lock free operation.

Note that the T cannot have a non-trivial dtor. I worked on a version that did allow for non-trivial dtors, that actually worked. But I found that it was easier just to make the T a pointer to the T that I wanted, where the producer released ownership, and the consumer acquired ownership. This of course requires that the T itself is allocated using lockfree methods, but the same allocator I made with the stack works here as well.

In any case the point of lock-free programming is not that the data structures themselves are slower. The points are this:

  1. lock free makes me independent of the scheduler. Lock-based programming depends on the scheduler to make sure that the holders of a lock are running so that they can release the lock. This is what causes "priority inversion" On Linux there are some lock attributes to make sure this happens
  2. If I am independent of the scheduler, the OS has a far easier time managing timeslices, and I get far less context switching
  3. it is easier to write correct multithreaded programs using lockfree methods since I dont have to worry about deadlock , livelock, scheduling, syncronization, etc This is espcially true with shared memory implementations, where a process could die while holding a lock in shared memory, and there is no way to release the lock
  4. lock free methods are far easier to scale. In fact, I have implemented lock free methods using messaging over a network. Distributed locks like this are a nightmare

That said, there are many cases where lock-based methods are preferable and/or required

  1. when updating things that are expensive or impossible to copy. Most lock free methods use some sort of versioning, i.e. make a copy of the object, update it, and check if the shared version is still the same as when you copied it, then make the current version you update version. Els ecopy it again, apply the update, and check again. Keep doing this until it works. This is fine when the objects are small, but it they are large, or contain file handles, etc then not recommended
  2. Most types are impossible to access in a lock free way, e.g. any STL container. These have invariants that require non atomic access , for example assert(vector.size()==vector.end()-vector.begin()). So if you are updating/reading a vector that is shared, you have to lock it.

This is an old question, but no one has provided an accepted solution. So I offer this info for others who may be searching.

This website: http://www.1024cores.net

Provides some really useful lockfree/waitfree data structures with thorough explanations.

What you are seeking is a lock-free solution to the reader/writer problem.

See: http://www.1024cores.net/home/lock-free-algorithms/reader-writer-problem


For a traditional one-block circular buffer I think this simply cannot be done safely with atomic operations. You need to do so much in one read. Suppose you have a structure that has this:

uint8_t* buf;
unsigned int size; // Actual max. buffer size
unsigned int length; // Actual stored data length (suppose in write prohibited from being > size)
unsigned int offset; // Start of current stored data

On a read you need to do the following (this is how I implemented it anyway, you can swap some steps like I'll discuss afterwards):

  1. Check if the read length does not surpass stored length
  2. Check if the offset+read length do not surpass buffer boundaries
  3. Read data out
  4. Increase offset, decrease length

What should you certainly do synchronised (so atomic) to make this work? Actually combine steps 1 and 4 in one atomic step, or to clarify: do this synchronised:

  1. check read_length, this can be sth like read_length=min(read_length,length);
  2. decrease length with read_length: length-=read_length
  3. get a local copy from offset unsigned int local_offset = offset
  4. increase offset with read_length: offset+=read_length

Afterwards you can just do a memcpy (or whatever) starting from your local_offset, check if your read goes over circular buffer size (split in 2 memcpy's), ... . This is 'quite' threadsafe, your write method could still write over the memory you're reading, so make sure your buffer is really large enough to minimize that possibility.

Now, while I can imagine you can combine 3 and 4 (I guess that's what they do in the linked-list case) or even 1 and 2 in atomic operations, I cannot see you do this whole deal in one atomic operation :).

You can however try to drop 'length' checking if your consumers are very smart and will always know what to read. You'd also need a new woffset variable then, because the old method of (offset+length)%size to determine write offset wouldn't work anymore. Note this is close to the case of a linked list, where you actually always read one element (= fixed, known size) from the list. Also here, if you make it a circular linked list, you can read to much or write to a position you're reading at that moment!

Finally: my advise, just go with locks, I use a CircularBuffer class, completely safe for reading & writing) for a realtime 720p60 video streamer and I have got no speed issues at all from locking.


This is an old question but no one has provided an answer that precisely answers it. Given that still comes up high in search results for (nearly) the same question, there should be an answer, given that one exists.

There may be more than one solution, but here is one that has an implementation: https://github.com/tudinfse/FFQ The conference paper referenced in the readme details the algorithm.

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