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We have the following serial C code operating on

two vectors a[] and b[]:

double a[20000],b[20000],r=0.9;

for(int i=1;i<=10000;++i)

Please tell us on how to port this code to CUDA and cublas?

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2 Answers 2

It's also possible to implement this reduction in Thrust using thrust::transform_reduce. This solution fuses the entire operation, as talonmies suggests:

#include <thrust/device_vector.h>
#include <thrust/iterator/zip_iterator.h>
#include <thrust/transform_reduce.h>
#include <thrust/functional.h>

// this functor unpacks a tuple and then computes
// a weighted absolute difference of its members
struct weighted_absolute_difference
  double r;

  weighted_absolute_difference(const double r)
    : r(r)

  __host__ __device__
  double operator()(thrust::tuple<double,double> t)
    double a = thrust::get<0>(t);
    double b = thrust::get<1>(t);

    a = r * a + (1.0 - r) * b;

    return fabs(a - b);

int main()
  using namespace thrust;

  const std::size_t n = 20000;

  const double r = 0.9;

  device_vector<double> a(n), b(n);

  // initialize a & b

  // do the reduction
  double result =
    transform_reduce(make_zip_iterator(make_tuple(a.begin(), b.begin())),
                     make_zip_iterator(make_tuple(a.end(),   b.end())),

  // note that this solution does not set
  // a[i] = r * a[i] + (1 - r) * b[i]

  return 0;

Note that we do not perform the assignment a[i] = r * a[i] + (1 - r) * b[i] in this solution, though it would be simple to do so after the reduction using thrust::transform. It is not safe to modify transform_reduce's arguments in either functor.

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Nice solution, just need to fix a.end() appearing twice where the second one should be b.end() and to mention that the result is the return value of transform_reduce. –  jmsu Nov 24 '11 at 10:18
@jmsu Thanks; fixed. –  Jared Hoberock Nov 24 '11 at 15:13

This second line in your loop:


is known as a reduction. Fortunately there is reduction example code in the CUDA SDK - take a look at this and use it as a template for your algorithm.

You probably want to split this into two separate operations (possibly as two separate kernels) - one for the parallel part (calculation of bp[] values) and a second for the reduction (calculate errors).

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Why would this need to be done using two operations? The computation and the reduction can be safely fused -- the whole thing is embarassingly parallel. –  talonmies Nov 23 '11 at 14:53
@talonmies: since the OP is evidently a CUDA noob I felt that it would be easier to use the reduction example from the CUDA SDK to do the reduction for errors and then they would just need a simple operation for the straightforward parallel part prior to the reduction. Not necessarily two kernels, although it would probably make it easier to debug. –  Paul R Nov 23 '11 at 14:57

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