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Lets say I have a data structure:

struct MyBigData {
    float * dataArray;
    float * targetArray;
    float * nodes;
    float * dataDataData;
}

I would like to be able to pass this structure around some various CUDA kernels. I don't want to have to pass multiple arrays as arguments, so can I just pass the structure and be done with it? I know the kernels support C structures, but how about dynamic memory in the C structures?

It seems I would just do this to make the structure on the CUDA card:

MyBigData * mbd = (MyBigData *) cudaMalloc( sizeof(MyBigData) );

But how about the dynamic memory for the arrays in the structure? This line below compiles but has a run-time error:

mbd->dataArray = (float *) cudaMalloc( 10 * sizeof(float) );

This is because cudaMalloc() runs on the CPU, and it cannot read the mdb->dataArray to set the pointer equal to the new memory address. So there's a run-time error. However, this compiles and runs, but doesn't seem to be what I want:

MyBigData * mbd = (MyBigData *) malloc( sizeof(myBigData) );
mbd->dataArray = (float *) cudaMalloc( 10 * sizeof(float) );

Because now, although this is valid, now mbd resides on the main system memory, and the float pointer points to memory allocated on the CUDA device. So I can't just pass a pointer to the MyBigData structure, I have to pass each variable in the structure to the kernel individually. Not clean. What I want is:

someKernel<<<1,1>>>(mbd);

Not:

someKernel<<<1,1>>>(mbd->dataArray, mbd->targetArray, mbd->nodes, mbd->dataDataData);

So I was thinking, how about cudaMemcpy()? I was thinking of this:

MyBigData *d_mbd = cudaMemcpy( (void*) &d_mbd, (void*) mbd, SOMESIZE, CudaHostToDevice);

But then what do I put for SOMESIZE? I can't use sizeof(MyBigData), because that will include the size of float pointers, not the actual size of the arrays. Second, is cudaMemcpy() even smart enough to dig down into sub-objects of a complicated data structure? I think not.

So, is it impossible to have a structure containing dynamic memory on the CUDA card? Or am I missing something. The easy way would be to have a CUDA kernel allocate some memory, but you can't call cudaMalloc() from a CUDA kernel.

Thoughts?

UPDATE 7 May: I wrote this code, and it compiles, but it tells me all the values are zero. I think I am creating the object correctly and populating the values properly with the CUDA Kernel. The values are just the thread ID. I suspect I'm not printing the values properly. Thoughts? And thank you!

MyBigData* generateData(const int size) {
    MyBigData *mbd_host, *mbd_cuda;
    mbd_host = (MyBigData *) malloc( sizeof(MyBigData) );
    cudaMalloc( (void**) &mbd_host->dataArray, size * sizeof(float) );
    cudaMalloc( (void**) &mbd_host->targetArray, size * sizeof(float) );
    cudaMalloc( (void**) &mbd_host->nodes, size * sizeof(float) );
    cudaMalloc( (void**) &mbd_host->dataDataData, size * sizeof(float) );
    cudaMalloc( (void**) &mbd_cuda, sizeof(MyBigData) );
    cudaMemcpy( mbd_cuda, mbd_host, sizeof(mbd_host), cudaMemcpyHostToDevice );
    free(mbd_host);
    return mbd_cuda;
}

void printCudaData(MyBigData* mbd_cuda, const int size) {
    MyBigData *mbd;
    cudaMemcpy( mbd, mbd_cuda, sizeof(mbd_cuda), cudaMemcpyDeviceToHost);
    MyBigData *mbd_host = (MyBigData *) malloc( sizeof(MyBigData));
    mbd_host->dataArray = (float*) malloc(size * sizeof(float));
    mbd_host->targetArray = (float*) malloc(size * sizeof(float));
    mbd_host->nodes = (float*) malloc(size * sizeof(float));
    mbd_host->dataDataData = (float*) malloc(size * sizeof(float));

    cudaMemcpy( mbd_host->dataArray, mbd->dataArray, size * sizeof(float), cudaMemcpyDeviceToHost);
    cudaMemcpy( mbd_host->targetArray, mbd->targetArray, size * sizeof(float), cudaMemcpyDeviceToHost);
    cudaMemcpy( mbd_host->nodes, mbd->nodes, size * sizeof(float), cudaMemcpyDeviceToHost);
    cudaMemcpy( mbd_host->dataDataData, mbd->dataDataData, size * sizeof(float), cudaMemcpyDeviceToHost);

    for(int i = 0; i < size; i++) {
        printf("data[%i] = %f\n", i, mbd_host->dataArray[i]);
        printf("target[%i] = %f\n", i, mbd_host->targetArray[i]);
        printf("nodes[%i] = %f\n", i, mbd_host->nodes[i]);
        printf("data2[%i] = %f\n", i, mbd_host->dataDataData[i]);
    }

    free(mbd_host->dataArray);
    free(mbd_host->targetArray);
    free(mbd_host->nodes);
    free(mbd_host->dataDataData);
    free(mbd_host);
}

This is my Kernel and the function that calls it:

__global__ void cudaInitData(MyBigData* mbd) {
    const int threadID = threadIdx.x;
    mbd->dataArray[threadID] = threadID;
    mbd->targetArray[threadID] = threadID;
    mbd->nodes[threadID] = threadID;
    mbd->dataDataData[threadID] = threadID;
}

void initData(MyBigData* mbd, const int size) {
    if (mbd == NULL)
        mbd = generateData(size);

    cudaInitData<<<size,1>>>(mbd);
}

My main() calls:

MyBigData* mbd = NULL;
initData(mbd, 10);
printCudaData(mbd, 10);
share|improve this question
1  
I am not a CUDA developer, but it sounds like what you're describing would very much not be possible the way you've described- when you're sharing pointers between two discreet memory blocks, things are just not going to work. The memcopy family of functions want a continuous block of data, which you don't have. What I am curious about is the constant 10- if your arrays are always length 10, why not build your data structure to be 4 * ((sizeof(float*) + (10 * sizeof(float)))? –  David Souther May 5 '12 at 3:14
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1 Answer 1

Second, is cudaMemcpy() even smart enough to dig down into sub-objects of a complicated data structure? I think not.

You re right, cudaMemcpy() does not make recursive copy. To achieve what you want, you should do something like this:

// Create mbd on host
MyBigData *mbd_host, *mbd;
mbd_host = (MyBigData *) malloc( sizeof(myBigData) );
// Fill it with pointers to device arrays
cudaMalloc( &mbd_host->dataArray, 10 * sizeof(float) );
// etc for other structure fields
// Create mbd on device
cudaMalloc( &mbd, sizeof(MyBigData) );
// Copy structure, filled with device addresses, to device memory
cudaMemcpy( mbd, mbd_host, sizeof(mbd), cudaMemcpyHostToDevice );
// Voila!

By the way, it's probably a good idea to store you MyBigData structure not in __global__, but in __constant__ memory of the device (you would have to declare a constant instead of allocating mbd with cudaMalloc and use cudaMemcpyToSymbol instead of last cudaMemcpy)

share|improve this answer
    
I've included some code above. I'm not sure I'm printing my values out correctly, everything is just zero but should be 0-9 since I call the Kernel with 10 threads, and set the values to be the thread ID. Am I retrieving the data from the GPU correctly for printing? –  Richard Żak May 7 '12 at 15:06
    
@RichardŻak In printCudaData you should first allocate mbd. Now it's just pointer to nowhere, and copyoing data to it is "undefined behaviour". Besides, always check return values from cuda... functions, an error might come from anywhere. –  aland May 7 '12 at 16:28
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