Cuda gridDim and blockDim

I get what blockDim is, but I have a problem with gridDim. Blockdim gives the size of the block, but what is gridDim? On the Internet it says gridDim.x gives the number of blocks in the x coordinate.

How can I know what blockDim.x * gridDim.x gives?

How can I know that how many gridDim.x values are there in the x line?

For example, consider the code below:

int tid = threadIdx.x + blockIdx.x * blockDim.x;
double temp = a[tid];
tid += blockDim.x * gridDim.x;

while (tid < count)
{
if (a[tid] > temp)
{
temp = a[tid];
}
tid += blockDim.x * gridDim.x;
}

I know that tid starts with 0. The code then has tid+=blockDim.x * gridDim.x. What is tid now after this operation?

• blockDim.x,y,z gives the number of threads in a block, in the particular direction
• gridDim.x,y,z gives the number of blocks in a grid, in the particular direction
• blockDim.x * gridDim.x gives the number of threads in a grid (in the x direction, in this case)

block and grid variables can be 1, 2, or 3 dimensional. It's common practice when handling 1-D data to only create 1-D blocks and grids.

In the CUDA documentation, these variables are defined here

In particular, when the total threads in the x-dimension (gridDim.x*blockDim.x) is less than the size of the array I wish to process, then it's common practice to create a loop and have the grid of threads move through the entire array. In this case, after processing one loop iteration, each thread must then move to the next unprocessed location, which is given by tid+=blockDim.x*gridDim.x; In effect, the entire grid of threads is jumping through the 1-D array of data, a grid-width at a time. This topic, sometimes called a "grid-striding loop", is further discussed in this blog article.

You might want to consider taking a couple of the introductory CUDA webinars available on the NVIDIA webinar page. For example, these 2:

• GPU Computing using CUDA C – An Introduction (2010) An introduction to the basics of GPU computing using CUDA C. Concepts will be illustrated with walkthroughs of code samples. No prior GPU Computing experience required
• GPU Computing using CUDA C – Advanced 1 (2010) First level optimization techniques such as global memory optimization, and processor utilization. Concepts will be illustrated using real code examples

It would be 2 hours well spent, if you want to understand these concepts better.

The general topic of grid-striding loops is covered in some detail here.

• @alrikai I was in the process of simply adding a few comments to your answer when you deleted it. (Then later you re-posted, I guess.) You were first, and your answer is fine. May 18 '13 at 0:54
• Yeah I had accidentally posted it about half-way through writing it (whoops) May 18 '13 at 1:00

Paraphrased from the CUDA Programming Guide:

gridDim: This variable contains the dimensions of the grid.

blockIdx: This variable contains the block index within the grid.

blockDim: This variable and contains the dimensions of the block.

You seem to be a bit confused about the thread hierachy that CUDA has; in a nutshell, for a kernel there will be 1 grid, (which I always visualize as a 3-dimensional cube). Each of its elements is a block, such that a grid declared as dim3 grid(10, 10, 2); would have 10*10*2 total blocks. In turn, each block is a 3-dimensional cube of threads.

With that said, it's common to only use the x-dimension of the blocks and grids, which is what it looks like the code in your question is doing. This is especially revlevant if you're working with 1D arrays. In that case, your tid+=blockDim.x * gridDim.x line would in effect be the unique index of each thread within your grid. This is because your blockDim.x would be the size of each block, and your gridDim.x would be the total number of blocks.

So if you launch a kernel with parameters

dim3 block_dim(128,1,1);
dim3 grid_dim(10,1,1);
kernel<<<grid_dim,block_dim>>>(...);

threadIdx.x range from [0 ~ 128)

blockIdx.x range from [0 ~ 10)

blockDim.x equal to 128

gridDim.x equal to 10

Hence in calculating threadIdx.x + blockIdx.x*blockDim.x, you would have values within the range defined by: [0, 128) + 128 * [1, 10), which would mean your tid values would range from {0, 1, 2, ..., 1279}. This is useful for when you want to map threads to tasks, as this provides a unique identifier for all of your threads in your kernel.

However, if you have

int tid = threadIdx.x + blockIdx.x * blockDim.x;
tid += blockDim.x * gridDim.x;

then you'll essentially have: tid = [0, 128) + 128 * [1, 10) + (128 * 10), and your tid values would range from {1280, 1281, ..., 2559} I'm not sure where that would be relevant, but it all depends on your application and how you map your threads to your data. This mapping is pretty central to any kernel launch, and you're the one who determines how it should be done. When you launch your kernel you specify the grid and block dimensions, and you're the one who has to enforce the mapping to your data inside your kernel. As long as you don't exceed your hardware limits (for modern cards, you can have a maximum of 2^10 threads per block and 2^16 - 1 blocks per grid)

• The concrete example was very helpful, thank you. Many people just repeat the definitions of gridDim, blockIdx, etc., but the example is vital.
– cmo
May 31 '13 at 16:15
• Excuse me sir, but at the final phrase you have said you can have a maximum of 2^10 threads per block and 2^16 - 1 blocks per thread but shouldn't it be: you can have a maximum of 2^10 threads per block and 2^16 - 1 blocks per grid May 19 '17 at 9:39

In this source code, we even have 4 threds, the kernel function can access all of 10 arrays. How?

#define N 10 //(33*1024)

int tid = threadIdx.x + blockIdx.x * gridDim.x;

if(tid < N)
c[tid] = 1;

while( tid < N)
{
c[tid] = 1;
tid += blockDim.x * gridDim.x;
}
}

int main(void)
{
int c[N];
int *dev_c;
cudaMalloc( (void**)&dev_c, N*sizeof(int) );

for(int i=0; i<N; ++i)
{
c[i] = -1;
}

cudaMemcpy(dev_c, c, N*sizeof(int), cudaMemcpyHostToDevice);

cudaMemcpy(c, dev_c, N*sizeof(int), cudaMemcpyDeviceToHost );

for(int i=0; i< N; ++i)
{
printf("c[%d] = %d \n" ,i, c[i] );
}

cudaFree( dev_c );
}

Why we do not create 10 threads ex) add<<<2,5>>> or add<5,2>>> Because we have to create reasonably small number of threads, if N is larger than 10 ex) 33*1024.

This source code is example of this case. arrays are 10, cuda threads are 4. How to access all 10 arrays only by 4 threads.

see the page about meaning of threadIdx, blockIdx, blockDim, gridDim in the cuda detail.

In this source code,

gridDim.x : 2    this means number of block of x

gridDim.y : 1    this means number of block of y

blockDim.x : 2   this means number of thread of x in a block

blockDim.y : 1   this means number of thread of y in a block

In add kernel function, we can access 0, 1, 2, 3 index of thread

->tid = threadIdx.x + blockIdx.x * blockDim.x

①0+0*2=0

②1+0*2=1

③0+1*2=2

④1+1*2=3

How to access rest of index 4, 5, 6, 7, 8, 9. There is a calculation in while loop

tid += blockDim.x + gridDim.x in while

** first call of kernel **

-1 loop: 0+2*2=4

-2 loop: 4+2*2=8

-3 loop: 8+2*2=12 ( but this value is false, while out!)

** second call of kernel **

-1 loop: 1+2*2=5

-2 loop: 5+2*2=9

-3 loop: 9+2*2=13 ( but this value is false, while out!)

** third call of kernel **

-1 loop: 2+2*2=6

-2 loop: 6+2*2=10 ( but this value is false, while out!)

** fourth call of kernel **

-1 loop: 3+2*2=7

-2 loop: 7+2*2=11 ( but this value is false, while out!)

So, all index of 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 can access by tid value.

First, see this figure Grid of thread blocks from the CUDA official document

Usually, we use kernel as this:

__global__ void kernelname(...){
const id_x = blockDim.x * blockIdx.x + threadIdx.x;
const id_y = blockDim.y * blockIdx.y + threadIdx.y;
...
}

// invoke kernel
// assume we have assigned the proper gridsize and blocksize
kernelname<<<gridsize, blocksize>>>(...)

The meaning of some variables:

gridsize the number of blocks per grid, corresponding to the gridDim

blocksize the number of threads per block, corresponding to the blockDim

blockIdx.x varies in [0, gridDim.x)

So, let's try to calculate the index at the x direction when we have threadIdx.x and blockIdx.x. According to the figure, blockIdx.x determines which block you are, and threadIdx.x determines which thread you are when the location of block is given. Hence, we have:

which_blk = blockDim.x * blockIdx.x; // which block you are
final_index_x = which_blk + threadIdx.x; // based on the given block, we can have the final location by adding the threadIdx.x

that is:

final_index_x = blockDim.x * blockIdx.x + threadIdx.x;

which is same as the sample code above.

Similarly, we can get the index at y or z direction respectively.

As we can see, we usually don't use gridDim in our code, because this information is performed as the range of blockIdx. On the contrary, we have to use blockDim although this information is performed as the range of threadIdx. The reason I have shown above step by step.