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So I've been working on program in which I'm creating a hash table in global memory. The code is completely functional (albeit slower) on a GTS250 which is a Compute 1.1 device. However, on a Compute 2.0 device (C2050 or C2070) the hash table is corrupt (data is incorrect and pointers are sometimes wrong).

Basically the code works fine when only one block is utilized (both devices). However, when 2 or more blocks are used, it works only on the GTS250 and not on any Fermi devices.

I understand that the warp scheduling and memory architecture between the two platforms are different and I am taking that into account when developing the code. From my understanding, using __theadfence() should make sure any global writes are committed and visible to other blocks, however, from the corrupt hash table, it appears that they are not.

I've also posted the problem on the NVIDIA CUDA developer forum and it can be found here.

Relevant code below:

__device__ void lock(int *mutex) {
    while(atomicCAS(mutex, 0, 1) != 0);
}

__device__ void unlock(int *mutex) {
    atomicExch(mutex, 0);
}

__device__ void add_to_global_hash_table(unsigned int key, unsigned int count, unsigned int sum, unsigned int sumSquared, Table table, int *globalHashLocks, int *globalFreeLock, int *globalFirstFree)
{
    // Find entry if it exists
    unsigned int hashValue = hash(key, table.count);

    lock(&globalHashLocks[hashValue]);

    int bucketHead = table.entries[hashValue];
    int currentLocation = bucketHead;

    bool found = false;
    Entry currentEntry;

    while (currentLocation != -1 && !found) {
        currentEntry = table.pool[currentLocation];
        if (currentEntry.data.x == key) {
            found = true;
        } else {
            currentLocation = currentEntry.next;
        }
    }

    if (currentLocation == -1) {
        // If entry does not exist, create entry
        lock(globalFreeLock);
        int newLocation = (*globalFirstFree)++;
        __threadfence();
        unlock(globalFreeLock);

        Entry newEntry;
        newEntry.data.x = key;
        newEntry.data.y = count;
        newEntry.data.z = sum;
        newEntry.data.w = sumSquared;
        newEntry.next = bucketHead;

        // Add entry to table
        table.pool[newLocation] = newEntry;
        table.entries[hashValue] = newLocation;
    } else {
        currentEntry.data.y += count;
        currentEntry.data.z += sum;
        currentEntry.data.w += sumSquared;
        table.pool[currentLocation] = currentEntry;
    }

    __threadfence();
    unlock(&globalHashLocks[hashValue]);
}
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That device function isn't enough code to say what is wrong. The correct operation of the device function depends on the integrity of lock and unlock correctly protecting the critical section, but how do they work? –  talonmies Apr 4 '11 at 15:04
    
Just added the lock/unlock code. –  achinda99 Apr 4 '11 at 15:08
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2 Answers

up vote 0 down vote accepted

As pointed out by LSChien in this post, the issue is with L1 cache coherency. While using __threadfence() will guarantee shared and global memory writes are visible to other threads, since it is not atomic, thread x in block 1 may reach a cached memory value until thread y in block 0 has executed to the threadfence instruction. Instead LSChien suggested a hack in his post of using an atomicCAS() to force the thread to read from global memory instead of a cached value. The proper way to do this is by declaring the memory as volatile, requiring that every write to that memory be visible to all other threads in the grid immediately.

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1  
In CUDA volatile actually means that a value must be written back to memory immediately from register. It makes no guarantees about the timeliness of when the write will be visible to another thread. The effect is to prevent the compiler from applying any optimisations which would result in a memory store instruction from being removed from code and an intermediate result carried from operation to operation in register. –  talonmies Apr 9 '11 at 8:14
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__threadfence guarantees that writes to global memory are visible to other threads in the current block before returning. That is not the same as "write operation on global memory is complete"! Think caching on each multicore.

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2  
No, that is what __threadfence_block does. __threadfence ensures global memory transactions are visible to all threads at the device level. –  talonmies Apr 4 '11 at 16:18
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