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Short question: May I use __syncthreads() in a block where I have purposedly dropped threads using return, without creating a deadlock?


Long question:

I have a kernel that works on an input array in several steps.

  1. First, if the kernel was launched with excess threads, they are dropped through a classic return.
  2. Then, the kernel processes the data with 1 thread per element, not less.
  3. Lastly, the kernel drops the last thread through a return and processes the data except for the last element, whose thread was dropped.

Step 2 and 3 call __syncthreads() several times.

The documentation states that __syncthreads() must be called by every thread in the block (else it will lead to a deadlock), but in practice I have never experienced such behavior.

Hence my question: is it safe to drop excess threads using return, and later call __syncthreads() to synchronize the remaining threads?


Sample code:

template<typename T>
struct ArrayWrapper {
    T* data;
    int size;
}

__global__ void myKernel(ArrayWrapper<float> input) {
    // Drop excess threads if user put too many in kernel call
    // After the return, we have exactly (input.size) threads
    if (threadIdx.x >= input.size) {
        return;
    }

    __syncthreads(); //<! Is this safe?

    // The rest of the algorithm works differently
    // For that we need to drop ONE thread (the "last")
    // After the return, we have exactly (input.size - 1) threads
    if (threadIdx.x + 1 == input.size) {
        return;
    }

    __syncthreads(); //<! Is this safe?
}
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1 Answer 1

up vote 15 down vote accepted

The answer to the short question is "No". Warp level branch divergence around a __syncthreads() instruction will cause a deadlock and result in a kernel hang. Your code example is not guaranteed to be safe or correct. The correct way to implement the code would be like this:

__global__ void kernel(...)

    if (tidx < N) {
        // Code stanza #1
    }

    __syncthreads();


    if (tidx < N) {
        // Code stanza #2
    }

    // etc
}

so that the __syncthreads() instructions are executed unconditionally.


EDIT: Just to add a bit of additional information which confirms this assertion, __syncthreads() calls get compiled into the PTX bar.sync instruction on all architectures. The PTX2.0 guide (p133) documents bar.sync and includes the following warning:

Barriers are executed on a per-warp basis as if all the threads in a warp are active. Thus, if any thread in a warp executes a bar instruction, it is as if all the threads in the warp have executed the bar instruction. All threads in the warp are stalled until the barrier completes, and the arrival count for the barrier is incremented by the warp size (not the number of active threads in the warp). In conditionally executed code, a bar instruction should only be used if it is known that all threads evaluate the condition identically (the warp does not diverge). Since barriers are executed on a per-warp basis, the optional thread count must be a multiple of the warp size.

So despite any assertions to the contrary, it is not safe to have conditional branching around a __syncthreads() call unless you can be 100% certain that every thread in any given warp follows the same code path and no warp divergence can occur.

share|improve this answer
    
interesting: even the thread count must be a multiple of the warp size. It makes sense of course, but is not straight from the beginning –  fabrizioM Jul 12 '11 at 19:57
    
@fabrizioM: The thread count they are talking about is only an optional argument to the bar instruction, and it only exists in PTX 2.0 and newer. I don't believe that the compiler currently generates code which specifies the thread count, and I am not even sure that the assembler will honor the argument and do anything with it anyway. –  talonmies Jul 12 '11 at 20:16
    
Thank you for the answer. It's a bit annoying because it will make me have multiple nested-ifs. But I guess that's better than a kernel hang. (Funnily enough, it has never hung so far with return). –  Park Young-Bae Jul 13 '11 at 8:29
    
@Cicada: to avoid nested-ifs, you could repeat the first test: if (threadIdx.x < input.size && threadIdx.x + 1 != input.size) –  jopasserat Jul 13 '11 at 8:45

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