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I just started porting one of my old codes to CUDA. I am using CUDA 5, with a GTX 690 card. It has 2 devices with compute capability 3.0. I have already coded a basic version. Now I need some insight into improving performance further.

I have 2 CUDA kernels. Kernel_1 reads 2 arrays, say Data_1 and Data_2, and produces results in Data_3. Kernel_2 refines the result in Data_3, while reading Data_1 and Data_2. Data_3 is later used in some other kernels. Data_1's values are used to guide "which regions of" Data_2 to read.

So currently I have the following setup :

Input(Data_1,Data_2)  // in host
cudaMemcpy(Data_1, Host2Device)
cudaMemcpy(Data_2, Host2Device)
cudaMalloc(Data_3)  // will be used in other kernels and later copy back to host
Kernel_1<<< >>>(const Data_1, const Data_2, Data_3)
Kernel_2<<< >>>(const Data_1, const Data_2, Data_3)
use(Data_3)

My first thought is should I allocate Data_1 and Data_2 as pinned and write combined memory in the host ? (I have 4GB ram in host and I may need at most 1.5-2GB for both Data_1 and Data_2 ... I am running Fedora 16. While running this program I will not run any other major process).

Now the writing into regions of Data_3 is independent of each other, and can be logically partitioned. So I was thinking that I should partition kernels 1 and 2 to operate on each half of the data on each of my device and later merge the results. So I was thinking something along the lines of :

for Device_i in NumDevices   // in my case 2, run 2 parallel CPU threads for this
{
    cudaSetDevice(Device_i);
    cudaMemcpy(Data_1 and Data_2, H2D);

    for Streams_j in NumStreams     // again 2 as i have 1 copy engine
    {
       kernel_1<<< Streams_j>>>();      // work on apt part of Data_1, Data_2 and Data_3
       Kernel_2<<<Streams_j>>>();       // work on apt part of Data_1, Data_2 and Data_3
    }
}

// merge Data_3 in Device 0, where later kernels are going to be called
cudaSetDevice(0);
cudaMemcpyPeer(2nd Half of Data_3,0,2nd Half of Data_3, 1, sizeof(Data_3)/2)

Is the above method viable ? Is there any other (possibly better/more efficient) way ? Is cudaMemcpyPeer the only way ? Currently the kernels need to access random parts of Data_1 and Data_2, so we need the whole arrays to be input to the kernels. I am also thinking about reordering the data so that I can use asynchronous memcpy, along with kernel executions.

Any advice or insight or criticism is highly appreciated.

share|improve this question
    
First, I'd recommend splitting the question in two. I have some thoughts about the first part. You did not specify if Data_1 and Data_2 have dependencies between each other so I assume they don't. What I'd do is overlap memory transfers and computations. Here developer.nvidia.com/content/how-overlap-data-transfers-cuda-cc you can see an example of overlapping. I would use the NON-DEFAULT streams for that. –  KiaMorot Jun 5 '13 at 11:37
    
@KiaMorot, my bad ... Data_1 and Data_2 are "dependent" as follows : I need to reads parts of Data_2 based on certain values of Data_1. I will edit the Question. Thanks for the reference link. –  sas1138 Jun 5 '13 at 12:16

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