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I want to implement a Inter-block barrier on CUDA, but encountering a serious problem.

I cannot figure out why it does not work.

#include <iostream>
#include <cstdlib>
#include <ctime>

#define SIZE 10000000
#define BLOCKS 100 

using namespace std;

struct Barrier {
    int *count;

    __device__ void wait() {
        atomicSub(count, 1);

    Barrier() {
        int blocks = BLOCKS;
        cudaMalloc((void**) &count, sizeof(int));
        cudaMemcpy(count, &blocks, sizeof(int), cudaMemcpyHostToDevice);

    ~Barrier() {

__global__ void sum(int* vec, int* cache, int *sum, Barrier barrier)
    int tid = blockIdx.x;

    int temp = 0;
    while(tid < SIZE) {
        temp += vec[tid];
        tid += gridDim.x;

    cache[blockIdx.x] = temp;


    if(blockIdx.x == 0) {
        for(int i = 0 ; i < BLOCKS; ++i)
            *sum += cache[i];

int main()
    int* vec_host = (int *) malloc(SIZE * sizeof(int));    
    for(int i = 0; i < SIZE; ++i)
        vec_host[i] = 1;

    int *vec_dev;
    int *sum_dev;
    int *cache;
    int sum_gpu = 0;

    cudaMalloc((void**) &vec_dev, SIZE * sizeof(int));
    cudaMemcpy(vec_dev, vec_host, SIZE * sizeof(int), cudaMemcpyHostToDevice);
    cudaMalloc((void**) &sum_dev, sizeof(int));
    cudaMemcpy(sum_dev, &sum_gpu, sizeof(int), cudaMemcpyHostToDevice);
    cudaMalloc((void**) &cache, BLOCKS * sizeof(int));
    cudaMemset(cache, 0, BLOCKS * sizeof(int));

    Barrier barrier;
    sum<<<BLOCKS, 1>>>(vec_dev, cache, sum_dev, barrier);

    cudaMemcpy(&sum_gpu, sum_dev, sizeof(int), cudaMemcpyDeviceToHost);

    return 0;

In fact, even if I rewrite the wait() as the following

    __device__ void wait() {
        while(*count != 234124)

The program exits normally. But I expect to get an infinite loop in this case.

share|improve this question
I suspect your kernel is actually crashing due to dereferencing a bad pointer inside Barrier::wait. Use cudaGetLastError to check for an error during the kernel. – Jared Hoberock Oct 9 '11 at 20:36
up vote 17 down vote accepted

Unfortunately, what you want to achieve (inter-block communication/synchronization) isn't strictly possible in CUDA. The CUDA programming guide states that "thread blocks are required to execute independently: It must be possible to execute them in any order, in parallel or in series." The reason for this restriction is to allow flexibility in the thread block scheduler, and to allow the code to agnostically scale with the number of cores. The only supported inter-block synchronization method is to launch another kernel: kernel launches (within the same stream) are implicit synchronization points.

Your code violates the block independence rule because it implicitly assumes that your kernel's thread blocks execute concurrently (cf. in parallel). But there's no guarantee that they do. To see why this matters to your code, let's consider a hypothetical GPU with only one core. We'll also assume that you only want to launch two thread blocks. Your spinloop kernel will actually deadlock in this situation. If thread block zero is scheduled on the core first, it will loop forever when it gets to the barrier, because thread block one never has a chance to update the counter. Because thread block zero is never swapped out (thread blocks execute to their completion) it starves thread block one of the core while it spins.

Some folks have tried schemes such as yours and have seen success because the scheduler happened to serendipitously schedule blocks in such a way that the assumptions worked out. For example, there was a time when launching as many thread blocks as a GPU has SMs meant that the blocks were truly executed concurrently. But they were disappointed when a change to the driver or CUDA runtime or GPU invalidated that assumption, breaking their code.

For your application, try to find a solution which doesn't depend on inter-block synchronization, because (barring a signification change to the CUDA programming model) it just isn't possible.

share|improve this answer
You're right. In essence, the answer is "don't do it". – Patrick87 Oct 9 '11 at 21:56
What about threadFenceReduction example from latest CUDA SDK? They don't do barrier-synchronization there, but achieve similar result to what topic starter wants by using global memory-fence (actually, the code is pretty much the same, but instead of spin-lock they just check whether current block is the last to finish its execution). – aland Oct 10 '11 at 4:35
It may be possible to implement a sum with memory fences, but the OP's question was about inter-block synchronization. In any case, a reduction on the scale of the example in the OP is better implemented in a two-phase approach without relying on atomics. An even better idea is to simply call thrust::reduce. – Jared Hoberock Oct 10 '11 at 7:13

Block to block synchronization is possible. See this paper.
The paper doesn't go into great detail on how it works, but it relies on the operation of __syncthreads(); to create the pause-barrier for the current block,... while waiting for the other blocks to get to the sync point.

One item that isn't noted in the paper is that sync is only possible if the number of blocks is small enough or the number of SM's is large enough for the task on hand. i.e. If you have 4 SM's and are trying to sync 5 blocks,.. the kernel will deadlock.

With their approach, I've been able to spread a long serial task among many blocks, easily saving 30% time over a single block approach. i.e. The block-sync worked for me.

share|improve this answer
but then there is a contradiction with the previous answer? – isti_spl Feb 2 '14 at 20:15

Looks like compiler optimizations issue. I'm not good with reading PTX-code, but it looks like the compiler have omitted the while-loop at all (even when compiled with -O0):

.loc    3   41  0
cvt.u64.u32     %rd7, %ctaid.x; // Save blockIdx.x to rd7
ld.param.u64    %rd8, [__cudaparm__Z3sumPiS_S_7Barrier_cache];
mov.s32     %r8, %ctaid.x; // Now calculate ouput address
mul.wide.u32    %rd9, %r8, 4;
add.u64     %rd10, %rd8, %rd9;   [%rd10+0], %r5; // Store result to cache[blockIdx.x]
.loc    17  128 0
ld.param.u64    %rd11, [__cudaparm__Z3sumPiS_S_7Barrier_barrier+0]; // Get *count to rd11
mov.s32     %r9, -1; // put -1 to r9     %r10, [%rd11], %r9; // Do AtomicSub, storing the result to r10 (will be unused)
cvt.u32.u64     %r11, %rd7; // Put blockIdx.x saved in rd7 to r11
mov.u32     %r12, 0; // Put 0 to r12     %p3, %r11, %r12; // if(blockIdx.x == 0)
@%p3 bra    $Lt_0_5122;
ld.param.u64    %rd12, [__cudaparm__Z3sumPiS_S_7Barrier_sum];   %r13, [%rd12+0];
mov.s64     %rd13, %rd8;
mov.s32     %r14, 0;

In case of CPU code, such behavior is prevented by declaring the variable with volatile prefix. But even if we declare count as int __device__ count (and appropriately change the code), adding volatile specifier just breaks compilation (with errors loke argument of type "volatile int *" is incompatible with parameter of type "void *")

I suggest looking at threadFenceReduction example from CUDA SDK. There they are doing pretty much the same as you do, but the block to do final summation is chosen in runtime, rather than predefined, and the while-loop is eliminated, because spin-lock on global variable should be very slow.

share|improve this answer
threadFenceReduction is different in one key point: blocks which are not the last to execute will continue executing and terminate. This means that there will be a last block to execute. In the OP's scheme he wants all threads to wait until the last block has reached the barrier, but this can result in deadlock. – Tom Oct 10 '11 at 8:58
@Tom I don't say that the do exactly the same, but fence allows to achieve similar results (not in terms of instruction flow, but in terms of content of output array) – aland Oct 10 '11 at 9:00
Didn't say you do ;-) That's my point, the OP is trying to a global barrier which is a bad idea (see Jared's answer) but looking at his code he could achieve the desired effect in the same way as the threadFenceReduction sample. @anyoneelse reading this: threadfence is not the same as a barrier! Check out the Programming Guide or search online for "memory fence" for more information. – Tom Oct 10 '11 at 14:25

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