You can also have a 2D grid of 1-dimensional threadblocks, in order to get around the limitation of 65535 blocks per grid dimension (for pre-cc3.0 devices). This may be an easier way of extending a fundamentally 1-D problem past the limit without introducing a 2-D array representation for the data.

Let's assume we have a `DATA_ELEMENTS`

parameter defined to be the number of elements (one element per thread) that your kernel will work on. If `DATA_ELEMENTS`

is larger than 65535*1024, then you cannot handle them all using a 1-D grid, if each thread handles only 1 element.

you can leave your `THREADS_PER_BLOCK`

parameter the same. Your thread index calculation inside the kernel will change to something like:

```
int idx = threadIdx.x + (blockDim.x * ((gridDim.x * blockIdx.y) + blockIdx.x));
```

you will want to be sure to condition your kernel calculations with something like:

```
if (idx < DATA_ELEMENTS){
(kernel code)
}
```

Your grid dimensions will be as follows:

```
dim3 grid;
if (DATA_ELEMENTS > (65535*THREADS_PER_BLOCK)){ // create a 2-D grid
int gridx = 65535; // could choose another number here
int gridy = ((DATA_ELEMENTS+(THREADS_PER_BLOCK-1))/THREADS_PER_BLOCK)/gridx;
if ((((DATA_ELEMENTS+(THREADS_PER_BLOCK-1))/THREADS_PER_BLOCK)%gridx) != 0) gridy++;
grid.x=gridx;
grid.y=gridy;
grid.z=1;
}
else{ // create a 1-D grid
int gridx = (DATA_ELEMENTS+(THREADS_PER_BLOCK-1))/THREADS_PER_BLOCK;
grid.x=gridx;
grid.y=1;
grid.z=1;
}
```

and you would launch your kernel as:

```
kernel<<<grid, THREADS_PER_BLOCK>>>(...);
```

Another method to tackle this kind of problem is to create a 1-D grid of some dimension (let's say the total number of threads in the grid is `NUM_THREADS_PER_GRID`

), and have each thread work on more than one element in the array of data elements, using something like a for-loop or while-loop:

```
while (idx < DATA_ELEMENTS) {
(code to process an element)
idx += NUM_THREADS_PER_GRID
}
```