...or just the threads in the current warp or block?

Also, when the threads in a particular block encounter (in the kernel) the following line

__shared__  float srdMem[128];

will they just declare this space once (per block)?

They all obviously operate asynchronously so if Thread 23 in Block 22 is the first thread to reach this line, and then Thread 69 in Block 22 is the last one to reach this line, Thread 69 will know that it already has been declared?

  • 1
    Shared memory is allocated for each block separately, but not simultaneously. When the SM actually starts executing the block, shared memory is allocated at that time. – sgarizvi Mar 6 '13 at 7:19

The __syncthreads() command is a block level synchronization barrier. That means it is safe to be used when all threads in a block reach the barrier. It is also possible to use __syncthreads() in conditional code but only when all threads evaluate identically such code otherwise the execution is likely to hang or produce unintended side effects [4].

Example of using __syncthreads(): (source)

__global__ void globFunction(int *arr, int N) 
    __shared__ int local_array[THREADS_PER_BLOCK];  //local block memory cache           
    int idx = blockIdx.x* blockDim.x+ threadIdx.x;

    //...calculate results
    local_array[threadIdx.x] = results;

    //synchronize the local threads writing to the local memory cache

    // read the results of another thread in the current thread
    int val = local_array[(threadIdx.x + 1) % THREADS_PER_BLOCK];

    //write back the value to global memory
    arr[idx] = val;        

To synchronize all threads in a grid currently there is not native API call. One way of synchronizing threads on a grid level is using consecutive kernel calls as at that point all threads end and start again from the same point. It is also commonly called CPU synchronization or Implicit synchronization. Thus they are all synchronized.

Example of using this technique (source):

CPU synchronization

Regarding the second question. Yes, it does declare the amount of shared memory specified per block. Take into account that the quantity of available shared memory is measured per SM. So one should be very careful how the shared memory is used along with the launch configuration.

  • "Warning, this is dangerous code" by @harrism in the same source you refer to – Nikolaos Giotis Oct 19 '13 at 17:48
  • Synchronizing all threads in a grid is problematic since there are no guarantees that they will be executed simultaneously. The GPU can run only limited amount of threads and if kernel execution requires too much thread blocks, some of them should be finished before new blocks can be started. The limit depends on the GPU model as well as software environment (user may execute multiple GPU programs simultaneously), so kernels trying to synchronize all thread blocks are very dangerous. The right way is to finish one kernel and start another. – Bulat Feb 10 '16 at 12:10
  • @Bulat I have not have the chance to play with newer hardware than Fermi. Do you know if the dynamic parallelism, execute several kernels simultaneously introduced since Kepler, can address, in some way, this problem? – KiaMorot Feb 10 '16 at 13:03
  • D.P. allows to run kernels inside kernels, and wait for their execution. While it can be used to implement more complex synchr. scenarios, it can't avoid fundamental problem - GPUs implement task-based parallelism and you never know whether two tasks (kernel instances) will be executed parallel or sequential. Look at eprints.cs.vt.edu/archive/00001087/01/… if you really need inter-block synch – Bulat Feb 11 '16 at 21:34
  • @Bulat Yes, I am aware of this paper. At the time I used it for my research but I think it wasn't giving me enough performance. Anyway I just wanted to see if the DP was addressing this or it was different feature of the GPU. – KiaMorot Feb 12 '16 at 8:17

I agree with all the answers here but I think we are missing one important point here w.r.t first question. I am not answering second answer as it got answered perfectly in the above answers.

Execution on GPU happens in units of warps. A warp is a group of 32 threads and at one time instance each thread of a particular warp execute the same instruction. If you allocate 128 threads in a block its (128/32 = ) 4 warps for a GPU.

Now the question becomes "If all threads are executing the same instruction then why synchronization is needed?". The answer is we need to synchronize the warps that belong to the SAME block. __syncthreads does not synchronizes threads in a warp, they are already synchronized. It synchronizes warps that belong to same block.

That is why answer to your question is : __syncthreads does not synchronizes all threads in a grid, but the threads belonging to one block as each block executes independently.

If you want to synchronize a grid then divide your kernel (K) into two kernels(K1 and K2) and call both. They will be synchronized (K2 will be executed after K1 finishes).


__syncthreads() waits until all threads within the same block has reached the command and all threads within a warp - that means all warps that belongs to a threadblock must reach the statement.

If you declare shared memory in a kernel, the array will only be visible to one threadblock. So each block will have his own shared memory block.

  • This is actually not true. The shared array is allocated for every block in the device. – KiaMorot Mar 6 '13 at 8:02
  • 1
    @KiaMorot: I think you misunderstood something. There is nothing wrong with this answer. Shared memory is block scope, that is what the answer says, that is what your common says. Where is the contradiction? – talonmies Mar 6 '13 at 8:28
  • Upvoted. Even though this post answers both questions, I selected the other one because it answers the first question very clearly and with a lot of effort. – Wuschelbeutel Kartoffelhuhn Mar 6 '13 at 9:01

Existing answers have done a great job answering how __syncthreads() works (it allows intra-block synchronization), I just wanted to add an update that there are now newer methods for inter-block synchronization. Since CUDA 9.0, "Cooperative Groups" have been introduced, which allow synchronizing an entire grid of blocks (as explained in the Cuda Programming Guide). This achieves the same functionality as launching a new kernel (as mentioned above), but can usually do so with lower overhead and make your code more readable.


In order to provide further details, aside of the answers, quoting seibert:

More generally, __syncthreads() is a barrier primitive designed to protect you from read-after-write memory race conditions within a block.

The rules of use are pretty simple:

  1. Put a __syncthreads() after the write and before the read when there is a possibility of a thread reading a memory location that another thread has written to.

  2. __syncthreads() is only a barrier within a block, so it cannot protect you from read-after-write race conditions in global memory unless the only possible conflict is between threads in the same block. __syncthreads() is pretty much always used to protect shared memory read-after-write.

  3. Do not use a __syncthreads() call in a branch or a loop until you are sure every single thread will reach the same __syncthreads() call. This can sometimes require that you break your if-blocks into several pieces to put __syncthread() calls at the top-level where all threads (including those which failed the if predicate) will execute them.

  4. When looking for read-after-write situations in loops, it helps to unroll the loop in your head when figuring out where to put __syncthread() calls. For example, you often need an extra __syncthreads() call at the end of the loop if there are reads and writes from different threads to the same shared memory location in the loop.

  5. __syncthreads() does not mark a critical section, so don’t use it like that.

  6. Do not put a __syncthreads() at the end of a kernel call. There’s no need for it.

  7. Many kernels do not need __syncthreads() at all because two different threads never access the same memory location.

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