Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

# AMP C++ speed up volume calculation

• Device : Tesla C2050
• OS : Windows 7 Enterprise
• IDE : VS 2012

Hello everyone. I'm using AMP C++ to do some volume calculations.

I have millions tetrahedrons with one point at (0,0,0). so I can get the volume of the tetrahedrons in a simple way:

``````sum += triangle.x1 * triangle.y2 * triangle.z3 + \
triangle.y1 * triangle.z2 * triangle.x3 + \
triangle.x2 * triangle.y3 * triangle.z1 - \
triangle.x3 * triangle.y2 * triangle.z1 - \
triangle.x2 * triangle.y1 * triangle.z3 - \
triangle.y3 * triangle.z2 * triangle.x1;
``````

So, I want to speed up my calculation by using AMP C++.

Here is the code.

``````typedef struct
{
double x1;
double y1;
double z1;
double x2;
double y2;
double z2;
double x3;
double y3;
double z3;
} Triangle;
``````

And the main function is:

``````accelerator my_accelerator(accelerator::default_accelerator);
accelerator_view acc_view = my_accelerator.get_default_view();

const int BLOCK_SIZE = 64;
int outputSize = int(numTriangles / BLOCK_SIZE);

int dimA = int(numTriangles / BLOCK_SIZE) * BLOCK_SIZE;
std::cout<<dimA<<std::endl;

//copy triangles from host to device
array<Triangle,1> triangle(numTriangles);
copy(vTriangle.begin(),vTriangle.end(), triangle);

//Volume
std::vector<double> volumeCPP;
for (int i=0; i < outputSize; i++)
{
volumeCPP.push_back(double(0));
}
array_view<double,1> volume(outputSize,volumeCPP);

clock_t start,finish;
start = clock();
parallel_for_each(
volume.extent.tile<1>(),
[=, &triangle](tiled_index<1> t_idx) restrict(amp)
{
double sum = 0.0f;
tile_static Triangle tile_triangle[4];
tile_triangle[t_idx.local[0]] = triangle[t_idx.global];
if (t_idx.local[0] == 0)
{
for (int idx=0; idx < BLOCK_SIZE; idx++){
sum += tile_triangle[idx].x1 * tile_triangle[idx].y2 * tile_triangle[idx].z3 + tile_triangle[idx].y1 * tile_triangle[idx].z2 * tile_triangle[idx].x3 + tile_triangle[idx].x2 * tile_triangle[idx].y3 * tile_triangle[idx].z1 - tile_triangle[idx].x3 * tile_triangle[idx].y2 * tile_triangle[idx].z1 - tile_triangle[idx].x2 * tile_triangle[idx].y1 * tile_triangle[idx].z3 - tile_triangle[idx].y3 * tile_triangle[idx].z2 * tile_triangle[idx].x1;
//t_idx.barrier.wait();
}
//t_idx.barrier.wait();
}
volume[t_idx.global] = sum;
}
);

acc_view.wait();
finish = clock();
copy(volume, volumeCPP.begin());
``````

So, every work has down. But interesting things is. It cost more than the CPU(single-core) code.

C++ on CPU(single-core) costs 0.085 seconds to finish 1024 * 1024 * 2 triangles calculation. But the AMP C++ code costs 0.530 seconds. much more than the c++ code.

After searching on the internet, there is a tip: If we warmed up the device first, we can get the "real" time costs on the calculation.

So I first calculate 128 triangles to warm up the device (costs about 0.2 seconds), then get the volume by calculating 1024 * 1024 * 2 triangles. It became much faster (costs about 0.091 seconds), but still slower than the CPU(single-core) code.

I'd like to know why, and anybody who can help me to speed up the calculation.

Thanks a lot.

-

Firstly, below is what I think is a slightly better implementation with some comments. You code is doing some things that can be avoided.

However, what you are really doing here is a reduction. This is an algorithm that has been very heavily researched and optimized. There is a C++ AMP implementation on AMP Algorithms Codeplex site It is implemented as an STL-style algorithm. Before concluding that C++ AMP does not meet your needs I would try using this reduce implementation as it will be trivial to do and may give you much better perf. I'd be interested to see how you get on.

The AMP Book Codeplex site contains a helper class for timing C++ AMP kernels. The accompanying book also discusses implementing reduction. It has an entire chapter on it.

``````void Foo()
{
const int numTriangles = 128;
std::vector<Triangle> vTriangle;

accelerator my_accelerator(accelerator::default_accelerator);
accelerator_view acc_view = my_accelerator.get_default_view();

const int BLOCK_SIZE = 64;
int outputSize = int(numTriangles / BLOCK_SIZE);

const int dimA = numTriangles;
std::cout<<dimA<<std::endl;

//copy triangles from host to device
// Use and array_view to automatically sync your data.
// You can use acc_view.flush() to make sure that copy is complete
// when you are running your timing code. Make this const so that AMP does
// not copy your input data back to the CPU.

array_view<const Triangle, 1> triangle(vTriangle.size(), vTriangle.data());

//Volume
// Don't push_back this causes (re)allocation as the vector grows.
// Set size and fill at the same time.

std::vector<double> volumeCPP(outputSize, 0.0);

array_view<double, 1> volume(outputSize, volumeCPP);

// I would use the timing code on CodePlex.
// It will be more accurate than this.
clock_t start, finish;
start = clock();
parallel_for_each(
// Not sure a tile size of 1 will be handled that
// well by the runtime in terms of perf. I see why you
// are doing it to get tile_static. You might be better off having larger tiles.

volume.extent.tile<1>(),
[=](tiled_index<1> t_idx) restrict(amp)
{
double sum = 0.0f;
for (int idx = 0; idx < BLOCK_SIZE; idx++)
{
// Loading the single triangle into tiled memory is a good idea because
// elements are read more than once.
tile_static Triangle tile_triangle;
tile_triangle = triangle[t_idx.global * BLOCK_SIZE + idx];

sum += tile_triangle.x1 * tile_triangle.y2 * tile_triangle.z3 +
tile_triangle.y1 * tile_triangle.z2 * tile_triangle.x3 +
tile_triangle.x2 * tile_triangle.y3 * tile_triangle.z1 -
tile_triangle.x3 * tile_triangle.y2 * tile_triangle.z1 -
tile_triangle.x2 * tile_triangle.y1 * tile_triangle.z3 -
tile_triangle.y3 * tile_triangle.z2 * tile_triangle.x1;
}
volume[t_idx.global] = sum;
}
);
// Force data copy back to CPU.
volume.synchronize();
double sum = std::accumulate(begin(volumeCPP), end(volumeCPP), 0.0);
}
``````

Here's a further example that uses the AMP Algorithms Library to implement a solution to your problem using a map/reduce pattern.

``````std::vector<Triangle> triangles_cpu(1000);

array_view<const Triangle, 1> triangles_gpu(triangles_cpu.size(), triangles_cpu.data());
concurrency::array<double, 1> volumes_gpu(triangles_cpu.size());
array_view<double, 1> volumes_gpuvw(volumes_gpu);
amp_stl_algorithms::transform(begin(triangles_gpu), end(triangles_gpu), begin(volumes_gpuvw),
[=](const triangle& t) restrict(amp)
{
return t.x1 * (t.y2 * t.z3 - t.y3 * t.z2)
+ t.y1 * (t.z2 * t.x3 - t.x2 * t.z3)
+ t.z1 * (t.x2 * t.y3 - t.x3 * t.y2);
});
double sum = amp_stl_algorithms::reduce(begin(volumes_gpuvw), end(volumes_gpuvw), 0.0);
``````
-
Hi, thanks for helping me and thanks for your tips. Following your advice, I modified my code, but only can see little improvement. Maybe AMP C++ is too new to use, we need wait for more time to let it be more complete. BTW, I'd like to use shared memory on my AMP C++ code, does it mean I have to upgrade my system to Win 8.1? I see an article shows shared memory is only supported on Win 8.1. – Zavier Xu Sep 5 '13 at 2:19
C++ AMP is fine. Have you tried increasing the tile size to improve the occupancy on the GPU? My code does not do this? A tile size of 1 will result in most of your GPU cores being idle. Have you tried using the timing code from Codeplex? This will make sure that you are not including any copy time in your timings I've also updated the answer with some additional code that uses the library I suggested. You might want to try that. – Ade Miller Sep 5 '13 at 22:29
Have you used the profiling tools in Visual Studio to see how much of your time is related to copying to the GPU and how much is calculation? It's pointless to move to 8.1 to eliminate the copy time if that's not what's taking the time. Always measure. And also, always listen to Ade :-) it served me well while writing the book especially on performance issues. – Kate Gregory Sep 7 '13 at 12:48
@Xaview Xu Did you try any of our suggestions? What were the results? – Ade Miller Sep 10 '13 at 14:26
@AdeMiller Sorry, I haven't check my box for a long time. Thanks for your answer, it helps me a lot. Thank you! – Zavier Xu Nov 4 '13 at 5:13

You should be able to speed it up a bit by factoring out.

Note that your formula for tetrahedron volume:

``````+ x1 * y2 * z3
+ y1 * z2 * x3
+ x2 * y3 * z1
- x3 * y2 * z1
- x2 * y1 * z3
- y3 * z2 * x1
``````

is equivalent to:

``````+ x1 * (y2 * z3 - y3 * z2)
+ y1 * (z2 * x3 - x2 * z3)
+ z1 * (x2 * y3 - x3 * y2)
``````

Original formula has 12 multiplications, and equivalent formula has 9 multiplications (25% less). It is hard to say how big of total improvement it will be, but I would not be surprised if it gives you 20%.

-
Thanks a lot, let me have a try. – Zavier Xu Sep 3 '13 at 8:26
No big difference between the former and latter one, it cost the same time to finish the calculation... I don't know why ... – Zavier Xu Sep 3 '13 at 8:31
Compilers are pretty smart these days and GPU compilers try very hard to emit as many FMAD operations as possible to improve arithmetic throughput. I would be very surprised if the compiler wasn't already doing this itself. – talonmies Sep 3 '13 at 8:45
@talonmies Yes you are right. And I think AMP C++ is not good enough to use today – Zavier Xu Sep 4 '13 at 6:14
@ZavierXu Given that you don't seem to have tried any of the things I suggested your conclusion that C++ AMP is "not good enough to use today" seems, at best, premature. – Ade Miller Nov 3 '13 at 22:07