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I'm new to OpenCL and in order to get a better grasp of a few concepts I contrived a simple example of a geometric progression as follows (emphasis on contrived):

  1. An array of N values and N coefficients (whose values could be anything, but in the example they all are the same) are allocated.
  2. M steps are performed in sequence where each value in the values array is multiplied by its corresponding coefficient in the coefficients array and assigned as the new value in the values array. Each step needs to fully complete before the next step can complete. I know this part is a bit contrived, but this is a requirement I want to enforce to help my understanding of OpenCL.
  3. I'm only interested in the values in the values array after the final step has completed.

Here is the very simple OpenCL kernel (MultiplyVectors.cl):

__kernel void MultiplyVectors (__global float4* x, __global float4* y, __global float4* result)
    int i = get_global_id(0);
    result[i] = x[i] * y[i];

And here is the host program (main.cpp):

#include <CL/cl.hpp>
#include <vector>
#include <stdio.h>
#include <stdlib.h>
#include <sys/types.h>

int main ()
    auto context = cl::Context (CL_DEVICE_TYPE_GPU);

    auto *sourceFile = fopen("MultiplyVectors.cl", "r");
    if (sourceFile == nullptr)
      perror("Couldn't open the source file");
      return 1;
    fseek(sourceFile, 0, SEEK_END);
    const auto sourceSize = ftell(sourceFile);
    auto *sourceBuffer = new char [sourceSize + 1];
    sourceBuffer[sourceSize] = '\0';
    fread(sourceBuffer, sizeof(char), sourceSize, sourceFile);
    auto program = cl::Program (context, cl::Program::Sources {std::make_pair (sourceBuffer, sourceSize + 1)});
    delete[] sourceBuffer;

    const auto devices = context.getInfo<CL_CONTEXT_DEVICES> ();
    program.build (devices);

    auto kernel = cl::Kernel (program, "MultiplyVectors");

    const size_t vectorSize = 1024;

    float coeffs[vectorSize] {};
    for (size_t i = 0; i < vectorSize; ++i)
        coeffs[i] = 1.000001;
    auto coeffsBuffer = cl::Buffer (context, CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR, sizeof (coeffs), coeffs);

    float values[vectorSize] {};
    for (size_t i = 0; i < vectorSize; ++i)
        values[i] = static_cast<float> (i);
    auto valuesBuffer = cl::Buffer (context, CL_MEM_READ_WRITE | CL_MEM_COPY_HOST_PTR, sizeof (values), values);

    kernel.setArg (0, coeffsBuffer);
    kernel.setArg (1, valuesBuffer);
    kernel.setArg (2, valuesBuffer);

    auto commandQueue = cl::CommandQueue (context, devices[0]);

    for (size_t i = 0; i < 1000000; ++i)
        commandQueue.enqueueNDRangeKernel (kernel, cl::NDRange (0), cl::NDRange (vectorSize / 4), cl::NullRange);

    printf ("All kernels enqueued.  Waiting to read buffer after last kernel...");

    commandQueue.enqueueReadBuffer (valuesBuffer, CL_TRUE, 0, sizeof (values), values);

    return 0;

What I'm basically asking is for advice on how to best optimize this OpenCL program to run on a GPU. I have the following questions based on my limited OpenCL experience to get the conversation going:

  1. Could I be handling the buffers better? I'd like to minimize any unnecessary ferrying of data between the host and the GPU.
  2. What's the optimal work group configuration (in general at least, I know this can very by GPU)? I'm not actually sharing any data between work items and it doesn't seem like I'd benefit from work groups much here, but just in case.
  3. Should I be allocating and loading anything into local memory for a work group (if that would at all makes sense)?
  4. I'm currently enqueing one kernel for each step, which will create a work item for each 4 floats to take advantage of a hypothetical GPU with a SIMD width of 128 bits. I'm attempting to enqueue all of this asynchronously (although I'm noticing the Nvidia implementation I have seems to block each enqueue until the kernel is complete) at once and then wait on the final one to complete. Is there a whole better approach to this that I'm missing?
  5. Is there a design that would allow for only one call to enqueueNDRangeKernel (instead of one call per step) while maintaining the ability for each step to be efficiently processed in parallel?

Obviously I know that the example problem I'm solving can be done in much better ways, but I wanted to have as simple of an example as possible that illustrated a vector of values being operated on in a series of steps where each step has to be completed fully before the next. Any help and pointers on how to best go about this would be greatly appreciated.


share|improve this question
For one, you don't need the special enqueue of the last step and the taking and waiting on the event. Just make your enqueueReadBuffer blocking and you're good. –  Dithermaster Jun 9 '14 at 22:59
1. Your buffer handling seems good 2. Specifying NULL for work group size allows the driver to determine. 3. Only if you re-use global reads within a work-group. Your example doesn't 4. That's the right way to do it. If M is really big you might need the occasional wait so you don't overflow the implementation's command queue. I don't think NVIDIA blocks right away, does it? Probably only after a number of enqueues. –  Dithermaster Jun 9 '14 at 23:02
Thanks for having a look and the info Dithermaster.I see your point regarding not needing the special kernel enqueue for the last step, as a enqueueReadBuffer at the end will cause that command to be executed after the last kernel enqueue and all should be good. –  Brandon Jun 10 '14 at 1:09
I actually do specify NULL for the work group size or at least that's what I understand the cl::NullRange to be equivalent to in the C++ API. I'll check and see if all of the equeueNDRangeKernel calls are blocking or just the later ones. I had read on a few places (including Nvidia's dev forums) that they had and may still have a bug where all of their equeueNDRangeKernel calls block. I understand from these same sources that AMD's implementation behaves differently. I'd love to test this out on an AMD device, but I don't have access to one. –  Brandon Jun 10 '14 at 1:14

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