I just started using C++ AMP, (as a way to learn it), and I'm **not** getting the expected results in terms of performance, maybe you can help me.

The problem to solve is very simple, I have a Vector and a Matrix structure (C++ code, btw I'm a newbie in C++)

```
struct Vector
{
public : float X, Y, Z;
};
struct Matrix
{
public : float M11, M12, M13, M14,
M21, M22, M23, M24,
M31, M32, M33, M34,
M41, M42, M43, M44;
};
```

The goal is to multiply the same Matrix over and over by millions of these vectors. Here goes the code that does the computation:

```
Vector compute(const Matrix matrix, const Vector vector) restrict(amp,cpu)
{
float tx = vector.X;
float ty = vector.Y;
float tz = vector.Z;
Vector result;
result.X = (matrix.M11 * tx) + (matrix.M12 * ty) + (matrix.M13 * tz) + matrix.M14;
result.Y = (matrix.M21 * tx) + (matrix.M22 * ty) + (matrix.M23 * tz) + matrix.M24;
result.Z = (matrix.M31 * tx) + (matrix.M32 * ty) + (matrix.M33 * tz) + matrix.M34;
return result;
}
```

Now I can call run this method in the CPU or in the GPU.

CPU:

```
Vector* cpu_compute(const Matrix matrix, const Vector *vectors, const int size)
{
Vector *result = (Vector*)malloc(size * sizeof(Vector));
for (int i = 0; i < size; ++i)
{
result[i] = compute(matrix, vectors[i]);
}
return result;
}
```

GPU:

```
Vector* gpu_compute(const Matrix matrix, const Vector *vectors, const int size)
{
Vector *result = (Vector*)malloc(size * sizeof(Vector));
array_view<const Vector, 1> vectors_view(size, vectors);
array_view<Vector, 1> result_view(size, result);
accelerator acc = pick_accelerator();
parallel_for_each(acc.default_view, vectors_view.extent, [=](index<1> idx) restrict(amp)
{
result_view[idx] = compute(matrix, vectors_view[idx]);
});
return result;
}
```

When running this code with 20.2 million vectors I get the following results:

- CPU (C++): 226ms
- CPU (C#) : 223ms
- GPU : 339ms

And I have several surprises. First the C# and C++ code run at almost the same speed. Second, the GPU is not as fast as I would hope.

I know that you have to pay a penalty in memory transfers, but I didn't think it would be that noticeable for this example.
No matter the amount of data I throw in, the GPU is **always** slower.
That means I'm doing something wrong, otherwise no one would use GPU to play games if they were beaten by a single core cpu.

Question: Is there a way this kind of computation can be more performant on the GPU than in the CPU?

Thanks

FYI: I'm running Windows 7, (which prevents me from using WARP), with an NVIDIA GeForce GTX 690 and an Intel Core i7 3930k.