# Parallelization in CUDA, assigning threads to each column

I'm new to cuda and am wondering how this is done. Say I have a 1d array converted from

a MxN 2d matrix, and I want to parallelize each column and do some operation,

how do I assign a thread to each column?

For example, if I have a 3x3 matrix:

1  2  3

4  5  6

7  8  9

And I want to add each number in the column depending on the column # (so 1st column will add 1 , 2nd will add 2....)

then it becomes

1+1   2+1   3+1

4+2   5+2   6+2

7+3   8+3   9+3

How do I do this in cuda? I know how to assign threads to all the elements in the array but I don't know how to assign thread to each column. So, what I want is to send each column (1 , 2 ,3 ) ( 4 , 5 ,6 ) (7 , 8 ,9) and do the operation. So, any help would be appreciated!!

Thanks!

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In your example you are adding numbers based on the row. Still, you know the row/column length of the matrix (you know it's MxN). What you could do is something like:

__global__ void MyAddingKernel(int* matrix, int M, int N)
{

int gid = threadIdx.x + blockDim.x*blockIdx.x;
//Let's add the row number to each element
matrix[ gid ] += gid % M;
//Let's add the column number to each element
matrix[ gid ] += gid % N;

}

If you wanted to add a different number, you could do something like:

matrix[ gid ] += my_col_number_function(gid%N);
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Oh Thanks for the reply, but what if I want to shift each element from the right to the left in each row instead of adding? So, in my example, the first row ( 1 2 3 ) would become (2 3 3 ) [keeping the last element the same] , ( 4 5 6 ) becomes ( 5 6 6 ) and ( 7 8 9 ) becomes ( 8 9 9) ? Is it possible do it like the addition operation you showed ? thanks! –  overloading Apr 26 '12 at 20:07
In this case something like matrix[ gid ] = (gid % N) ? matrix[gid + 1] : matrix[gid]; Might work. –  limes Apr 26 '12 at 20:19
modulo operator is a costly operation on the gpu, try to avoid it! –  djmj Apr 27 '12 at 0:23

Use a better grid layout to avoid those modulo operations.

Use the unique block index for the rows which is 64-bit range on latest Cuda.

Tiling input data is a general approach if calculated data is uniquely across a block (rows), especially for more complex calculations.

/*
* @param tileCount
*/
const unsigned long long int inColumnCount_s,
const int inTileCount_s)
{

//get unique block index
const unsigned long long int blockId = blockIdx.x //1D
+ blockIdx.y * gridDim.x //2D
+ gridDim.x * gridDim.y * blockIdx.z; //3D

/*
* check column ranges in case kernel is called
* with more blocks then columns
* (since its block wide following syncthreads are safe)
*/
if(blockId >= inColumnCount_s)
return;

const unsigned long long int threadId = blockId * blockDim.x + threadIdx.x;

/*
* calculate unique and 1 blockId
* maybe shared memory is overhead
* but it shows concept if calculation is more complex
*/
__shared__ unsigned long long int blockIdAnd1_s;
blockIdAnd1_s = blockId + 1;

unsigned long long int idx;

//loop over tiles
for(int i = 0; i < inTileCount_s)
{
//calculate new offset for sequence thread writes
idx = i * blockDim.x + threadIdx.x;
//check new index range in case column count is no multiple of blockDim.x
if(idx >= inColumnCount_s)
break;
inOutMat_g[idx] = blockIdAnd1_s;
}

}

Example Cuda 2.0:

mat[131000][1000]

Necessary blockCount = 131000 / 65535 = 2 for blockDim.y rounded up!

inTileCount_s = 1000 / 192 = 6 rounded up!

(192 Threads per Block = 100 occupancy on Cuda 2.0)

<<(65535, 2, 1), (192, 1, 1)>>addRowNumberToCells(mat, 1000, 6)

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