How are threads organized to be executed by a GPU?

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    The CUDA Programming Guide should be a good place to start for this. I would also recommend checking out the CUDA introduction from here. – Tom Mar 6 '10 at 19:44


If a GPU device has, for example, 4 multiprocessing units, and they can run 768 threads each: then at a given moment no more than 4*768 threads will be really running in parallel (if you planned more threads, they will be waiting their turn).


threads are organized in blocks. A block is executed by a multiprocessing unit. The threads of a block can be indentified (indexed) using 1Dimension(x), 2Dimensions (x,y) or 3Dim indexes (x,y,z) but in any case xyz <= 768 for our example (other restrictions apply to x,y,z, see the guide and your device capability).

Obviously, if you need more than those 4*768 threads you need more than 4 blocks. Blocks may be also indexed 1D, 2D or 3D. There is a queue of blocks waiting to enter the GPU (because, in our example, the GPU has 4 multiprocessors and only 4 blocks are being executed simultaneously).

Now a simple case: processing a 512x512 image

Suppose we want one thread to process one pixel (i,j).

We can use blocks of 64 threads each. Then we need 512*512/64 = 4096 blocks (so to have 512x512 threads = 4096*64)

It's common to organize (to make indexing the image easier) the threads in 2D blocks having blockDim = 8 x 8 (the 64 threads per block). I prefer to call it threadsPerBlock.

dim3 threadsPerBlock(8, 8);  // 64 threads

and 2D gridDim = 64 x 64 blocks (the 4096 blocks needed). I prefer to call it numBlocks.

dim3 numBlocks(imageWidth/threadsPerBlock.x,  /* for instance 512/8 = 64*/

The kernel is launched like this:

myKernel <<<numBlocks,threadsPerBlock>>>( /* params for the kernel function */ );       

Finally: there will be something like "a queue of 4096 blocks", where a block is waiting to be assigned one of the multiprocessors of the GPU to get its 64 threads executed.

In the kernel the pixel (i,j) to be processed by a thread is calculated this way:

uint i = (blockIdx.x * blockDim.x) + threadIdx.x;
uint j = (blockIdx.y * blockDim.y) + threadIdx.y;
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    If each block can run 768 threads, why use only 64? If you use the max limit of 768, you will have less blocks and so better performance. – Aliza Nov 14 '11 at 10:20
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    @Aliza : blocks are logical, the limit of 768 threads is for each physical processing unit. You use blocks according to the specifications of your problem in order to distribute the work to the threads. It is not likely that you can always use blocks of 768 threads for every problem you have. Imagine you have to process a 64x64 image (4096 pixels). 4096/768 = 5.333333 blocks ? – cibercitizen1 Nov 15 '11 at 10:26
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    block are logical, but each block is assigned to a core. if there are more blocks than core, the blocks are queued until cores become free. In your example you can use 6 blocks and have the extra threads do nothing(2/3 of the threads on the 6th block). – Aliza Nov 15 '11 at 12:59
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    @cibercitizen1 - I think Aliza's point is a good one: if possible, one wants to use as many threads per block as possible. If there is a constraint that requires fewer threads, better to explain why that might be the case in a second example (but still explain the simpler and more desirable case, first). – user227667 Nov 19 '12 at 21:08
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    @thouis Yes, maybe. But the case is that the amount of memory needed by each thread is application dependent. For instance, in my last program, each thread invokes a least-square optimizing function, requiring "a lot" of memory. So much, that blocks can't be bigger than 4x4 threads. Even so, the speedup obtained was dramatic, vs the sequential version. – cibercitizen1 Nov 22 '12 at 11:04

Suppose a 9800GT GPU:

  • it has 14 multiprocessors (SM)
  • each SM has 8 thread-processors (AKA stream-processors, SP or cores)
  • allows up to 512 threads per block
  • warpsize is 32 (which means each of the 14x8=112 thread-processors can schedule up to 32 threads)


A block cannot have more active threads than 512 therefore __syncthreads can only synchronize limited number of threads. i.e. If you execute the following with 600 threads:


then the kernel must run twice and the order of execution will be:

  1. func1 is executed for the first 512 threads
  2. func2 is executed for the first 512 threads
  3. func1 is executed for the remaining threads
  4. func2 is executed for the remaining threads


The main point is __syncthreads is a block-wide operation and it does not synchronize all threads.

I'm not sure about the exact number of threads that __syncthreads can synchronize, since you can create a block with more than 512 threads and let the warp handle the scheduling. To my understanding it's more accurate to say: func1 is executed at least for the first 512 threads.

Before I edited this answer (back in 2010) I measured 14x8x32 threads were synchronized using __syncthreads.

I would greatly appreciate if someone test this again for a more accurate piece of information.

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    What happens if func2() depends on the results of func1(). I think this is wrong – Chris Jan 4 '17 at 23:01
  • @Chris I wrote this seven years ago, but if I recall correctly i did a test on this and got this conclusion that kernels with more threads than gpu behave this way. If you happen to test this case and reached a different result then I'll have to delete this post. – Bizhan Jan 4 '17 at 23:41
  • Sorry I think this is wrong, also, that GPU can only concurrently run 112 threads. – Steven Lu May 11 '20 at 1:09
  • @StevenLu have you tried it? also I don't think 112 concurrent threads make any sense for a GPU. 112 is the number of stream processors. I can hardly remember CUDA now :) – Bizhan May 12 '20 at 15:15
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    @StevenLu the maximum number of threads is not the issue here, __syncthreads is a block-wide operation and the fact that it does not actually synchronize all threads is a nuisance for CUDA learners. So I updated my answer based on the information you gave me. I really appreciate it. – Bizhan May 13 '20 at 17:49

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