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I am aware that block sync is not possible, the only way is launching a new kernel.

BUT, let's suppose that I launch X blocks, where X corresponds to the number of the SM on my gpu. I should aspect that the scheduler will assign a block to each SM...right? And if the gpu is being utilized as a secondary graphic card (completely dedicated to Cuda), this means that, theoretically, no other process use it... right?

My idea is the following: implicit synchronization.

Let's suppose that sometimes I need only one block, and sometimes I need all the X blocks. Well, in those cases where I need just one block, I can configure my code so that the first block (or the first SM) will work on the "real" data while the other X-1 blocks (or SMs) on some "dummy" data, executing exactly the same instruction, just with some other offset. So that all of them will continue to be synchronized, until I am going to need all of them again.

Is the scheduler reliable under this conditions? Or you can be never sure?

share|improve this question

You've got several questions in one, so I'll try to address them separately.

One block per SM

I asked this a while back on nVidia's own forums, as I was getting results that indicated that this is not what happens. Apparently, the block scheduler will not assign a block per SM if the number of blocks is equal to the number of SMs.

Implicit synchronization

No. First of all, you cannot guarantee that each block will have its own SM (see above). Secondly, all blocks cannot access the global store at the same time. If they run synchronously at all, they will loose this synchronicity as of the first memory read/write.

Block synchronization

Now for the good news: Yes, you can. The atomic instructions described in Section B.11 of the CUDA C Programming Guide can be used to create a barrier. Assume that you have N blocks executing concurrently on your GPU.

__device__ int barrier = N;

__global__ void mykernel ( ) {

    /* Do whatever it is that this block does. */

    /* Make sure all threads in this block are actually here. */

    /* Once we're done, decrease the value of the barrier. */
    if ( threadIdx.x == 0 )
        atomicSub( &barrier , 1 );

    /* Now wait for the barrier to be zero. */
    if ( threadIdx.x == 0 )
        while ( atomicCAS( &barrier , 0 , 0 ) != 0 );

    /* Make sure everybody has waited for the barrier. */

    /* Carry on with whatever else you wanted to do. */


The instruction atomicSub(p,i) computes *p -= i atomically and is only called by the zeroth thread in the block, i.e. we only want to decrement barrier once. The instruction atomicCAS(p,c,v) sets *p = v iff *p == c and returns the old value of *p. This part just loops until barrier reaches 0, i.e. until all blocks have crossed it.

Note that you have to wrap this part in calls to __synchtreads() as the threads in a block do not execute in strict lock-step and you have to force them all to wait for the zeroth thread.

Just remember that if you call your kernel more than once, you should set barrier back to N.


In reply to jHackTheRipper's answer and Cicada's comment, I should have pointed out that you should not try to start more blocks than can be concurrently scheduled on the GPU! This is limited by a number of factors, and you should use the CUDA Occupancy Calculator to find the maximum number of blocks for your kernel and device.

Judging by the original question, though, only as many blocks as there are SMs are being started, so this point is moot.

share|improve this answer
wow, it looks great! :) Just some questions since I saw many other attempts similar to this one but all of them were failing because memory incoherence or cached barrier. Have you tried it? @Pedro – elect Jul 4 '12 at 11:31
@elect: Yes, I actually use this in my own code, albeit without the calls to __syncthread() since I only have 32 threads per block. If you're hesitant to take my word for it, you might want to check out Appendix A of "CUDA by Example: An Introduction to General-Purpose GPU Programming", in which atomic operations, mutual exclusion and synchronization between blocks are discussed. – Pedro Jul 4 '12 at 11:36
Perfect, so I guess it is working as supposed to do, did you not experience any issue, did you? On which hw? Fermi or Kepler? OS and Cuda software version? I was going to ask you about what you mean exactly with "you have only 32 threads/block" but then I got it, you meant that because you have only a warp/block, right? However, I am going to give a read to that Appendix just in case I find something else. By the way, thanks for your comment and the code :) @Pedro – elect Jul 4 '12 at 11:47
@djmj I know, but I am running an algorithm that has to run thousand of cycles. In each of these cycles, I need different degrees of parallelization, that is sometimes I need only one block of 34 threads and sometimes N blocks (always of 34 t) with N [1,34]. The point is that each kernel call as an overhead between 3-20 µs on NOT WDDM systems (where they say it is much higher). And right now I do be on win7 ^^ . However, I hope to switch as soon as possible to linux in order to have such a lower overheads. In any case, it'd be nice to avoid them completely, maybe with just a kernel call! :p – elect Jul 4 '12 at 14:20
@djmj Just want to update about kernel overheads in WDDM systems. They say no less than 40 µs (compare to the 3 µs). Likely to be higher. – elect Jul 5 '12 at 7:08

@Pedro is definitely wrong!

Achieving global synchronization has been the subject of several research works recently and, at last for non-Kepler architectures (I don't have one yet). The conclusion is always the same (or should be): it is not possible to achieve such a global synchronization across the whole GPU.

The reason is simple: CUDA blocks cannot be preempted, so given that you fully occupy the GPU, threads waiting for the barrier rendez-vous will never allow the block to terminate. Thus, it will not be removed from the SM, and will prevent the remaining blocks to run.

As a consequence, you will just freeze the GPU that will never be able to escape from this deadlock state.

-- edit to answer Pedro's remarks --

Such shortcomings have been noticed by other authors such as:

by the author of OpenCL in action

-- edit to answer Pedro's second remarks --

The same conclusion is made by @Jared Hoberock in this SO post: Inter-block barrier on CUDA

share|improve this answer
No, I am not "definitely wrong", otherwise this would not work in my own code. I have added a comment regarding the maximum number of blocks, which addresses your concerns regarding deadlocks. As for the "several research works" saying this is not possible, could you point me to one or two of them? – Pedro Jul 4 '12 at 13:01
this is not a matter of concurrently scheduled, but concurrently running blocks – jopasserat Jul 4 '12 at 13:06
How do you define concurrently running? You can schedule up to eight blocks per SM which will all run intermittently. While one block is spinning on the while-loop, the other blocks on the same SM can still run, filling the slots between each memory access. By the way, I'm still waiting for the "several research works". – Pedro Jul 4 '12 at 13:13
A note at the top of a blog post on OpenCL, i.e. not CUDA. That's not exactly "several research works". Please try harder, or at least post a counter-example in which this fails. If you're going to call other people's answers "definitely wrong", you're going to have to do a bit more work. – Pedro Jul 4 '12 at 13:24
After more than one year on Cuda, I am coming to the point that theory matters just until a certain point. I also thought that block sync was not possible after a lot of googling, but if Pedro says that it is working for him, I dont see why he should lie. Dont get me wrong, guys, I am not saying that one of you is right 100%, Im just saying that I am gonna give a try (as soon as I find some time to implement it :D ). I am sure that there are so many factor (both hw and sw) in the game and we should just figure out which of them matters. In any case, I will keep you both updated! :) elect – elect Jul 4 '12 at 14:12

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