public static void Execute(byte[] bitmap) { CudafyModule km = CudafyModule.TryDeserialize(); if (km == null || !km.TryVerifyChecksums()) { km = CudafyTranslator.Cudafy(typeof(SphereOpenCL), typeof(ray_opencl_const)); km.TrySerialize(); } GPGPU gpu = CudafyHost.GetDevice(CudafyModes.Target, CudafyModes.DeviceId); gpu.LoadModule(km); // capture the start time gpu.StartTimer(); // allocate memory on the GPU for the bitmap (same size as ptr) byte[] dev_bitmap = gpu.Allocate(bitmap); // allocate memory for the Sphere dataset //SphereOpenCL[] s = gpu.Allocate<SphereOpenCL>(SPHERES); // allocate temp memory, initialize it, copy to constant memory on the GPU SphereOpenCL[] temp_s = new SphereOpenCL[SPHERES]; for (int i = 0; i < SPHERES; i++) { temp_s[i].r = rnd(1.0f); temp_s[i].g = rnd(1.0f); temp_s[i].b = rnd(1.0f); temp_s[i].x = rnd(1000.0f) - 500; temp_s[i].y = rnd(1000.0f) - 500; temp_s[i].z = rnd(1000.0f) - 500; temp_s[i].radius = rnd(100.0f) + 20; } //gpu.CopyToDevice(temp_s, s); gpu.CopyToConstantMemory(temp_s, spheres); // generate a bitmap from our sphere data dim3 grids = new dim3(ray_gui.DIM / 16, ray_gui.DIM / 16); dim3 threads = new dim3(16, 16); //gpu.Launch(grids, threads).kernel(s, dev_bitmap); // Dynamic gpu.Launch(grids, threads, ((Action <GThread, byte[]>)thekernel), dev_bitmap); // Strongly typed // copy our bitmap back from the GPU for display gpu.CopyFromDevice(dev_bitmap, bitmap); // get stop time, and display the timing results float elapsedTime = gpu.StopTimer(); Console.WriteLine("Time to generate: {0} ms", elapsedTime); gpu.FreeAll(); }
public static float hit(SphereOpenCL s, float ox1, float oy1, ref float n1) { float dx = ox1 - s.x; float dy = oy1 - s.y; if (dx * dx + dy * dy < s.radius * s.radius) { float dz = GMath.Sqrt(s.radius * s.radius - dx * dx - dy * dy); n1 = dz / GMath.Sqrt(s.radius * s.radius); return(dz + s.z); } return(-2e10f); }