public static void IlGpu(CudaAccelerator gpu, Real[] result, Real[] left, Real[] right, int n)
{
using (var cudaResult = gpu.Allocate(result))
using (var cudaLeft = gpu.Allocate(left))
using (var cudaRight = gpu.Allocate(right))
{
using var blas = new CuBlas(gpu, CuBlasAPIVersion.V11);
var timer = Stopwatch.StartNew();
blas.Gemm(
CuBlasOperation.NonTranspose,
CuBlasOperation.NonTranspose,
n, n, n,
1, cudaLeft.View, n,
cudaRight.View, n, 0,
cudaResult.View, n);
gpu.Synchronize();
PrintPerformance(timer, "MatrixMultiplication.IlGpu.cuBLAS", n, n, n);
cudaResult.CopyTo(result, 0, 0, result.Length);
}
}
private static void IlGpuOptimisedImpl <TInt>(
CudaAccelerator gpu,
Real[] mSquaredDistances,
Real[] mCoordinates,
int c,
int n,
string name,
Action <ArrayView2D <Real>, ArrayView <Real>, TInt, int> kernelFunc,
Func <int, TInt> numCoordGetter)
where TInt : struct
{
using var cudaSquaredDistance = gpu.Allocate <Real>(n, n);
using var cudaCoordinates = gpu.Allocate(mCoordinates);
var timer = Stopwatch.StartNew();
const int blockSize = 128;
var gridSize = Util.DivUp(n, blockSize);
var lp = ((gridSize, gridSize, 1), (blockSize, 1, 1), SharedMemoryConfig.RequestDynamic <Real>(2 * c * blockSize));
gpu.Launch(kernelFunc, gpu.DefaultStream, lp, cudaSquaredDistance.View, cudaCoordinates.View, numCoordGetter(c), n);
gpu.Synchronize();
Util.PrintPerformance(timer, name, n, c, n);
cudaSquaredDistance.CopyTo(mSquaredDistances, (0, 0), 0, (n, n));
}
public static void IlGpu(
CudaAccelerator gpu,
Real[] mIntraReturn,
Real[] vClose,
Real[] vIsAlive,
Real[] vIsValidDay,
int m,
int n)
{
using (var cudaIntraReturn = gpu.Allocate(mIntraReturn))
using (var cudaClose = gpu.Allocate(vClose))
using (var cudaIsAlive = gpu.Allocate(vIsAlive))
using (var cudaIsValidDay = gpu.Allocate(vIsValidDay))
{
var timer = Stopwatch.StartNew();
var gridSizeX = Util.DivUp(n, 32);
var gridSizeY = Util.DivUp(m, 8);
var lp = ((gridSizeX, gridSizeY, 1), (32, 8));
gpu.Launch(IlGpuKernel, gpu.DefaultStream, lp, cudaIntraReturn.View, cudaClose.View, cudaIsAlive.View, cudaIsValidDay.View, m, n);
gpu.Synchronize();
Util.PrintPerformance(timer, "IntraReturn.IlGpu", 5, m, n);
cudaIntraReturn.CopyTo(mIntraReturn, 0, 0, mIntraReturn.Length);
}
}
public static float[] RunMatrixMul(float[][] a, float[][] b, int N)
{
//Create context and accelerator
var gpu = new CudaAccelerator(new Context());
//Create typed launcher
var matrixMulKernel = gpu.LoadAutoGroupedStreamKernel <
Index2,
ArrayView <float>,
ArrayView <float>,
ArrayView <float>,
int>(MatrixMul);
//Allocate memory
int buffSize = N * N;
MemoryBuffer <float> d_a = gpu.Allocate <float>(buffSize);
MemoryBuffer <float> d_b = gpu.Allocate <float>(buffSize);
MemoryBuffer <float> d_c = gpu.Allocate <float>(buffSize);
d_a.CopyFrom(FlatternArr(a), 0, Index1.Zero, buffSize);
d_b.CopyFrom(FlatternArr(b), 0, Index1.Zero, buffSize);
matrixMulKernel(new Index2(N, N), d_a.View, d_b.View, d_c.View, N);
// Wait for the kernel to finish...
gpu.Synchronize();
var c = d_c.GetAsArray();
return(c);
}
static void Main()
{
const int DataSize = 1024;
const CuBlasAPIVersion CuBlasVersion = CuBlasAPIVersion.V10;
using (var context = new Context())
{
// Enable algorithms library
context.EnableAlgorithms();
// Check for Cuda support
foreach (var acceleratorId in CudaAccelerator.CudaAccelerators)
{
using (var accelerator = new CudaAccelerator(context, acceleratorId))
{
Console.WriteLine($"Performing operations on {accelerator}");
var buf = accelerator.Allocate <float>(DataSize);
var buf2 = accelerator.Allocate <float>(DataSize);
accelerator.Initialize(accelerator.DefaultStream, buf, 1.0f);
accelerator.Initialize(accelerator.DefaultStream, buf2.View, 1.0f);
// Initialize the CuBlas library using manual pointer mode handling
// (default behavior)
using (var blas = new CuBlas(accelerator, CuBlasVersion))
{
// Set pointer mode to Host to enable data transfer to CPU memory
blas.PointerMode = CuBlasPointerMode.Host;
float output = blas.Nrm2(buf);
// Set pointer mode to Device to enable data transfer to GPU memory
blas.PointerMode = CuBlasPointerMode.Device;
blas.Nrm2(buf, buf2);
// Use pointer mode scopes to recover the previous pointer mode
using (var scope = blas.BeginPointerScope(CuBlasPointerMode.Host))
{
float output2 = blas.Nrm2(buf);
}
}
// Initialize the CuBlas<T> library using custom pointer mode handlers
using (var blas = new CuBlas <CuBlasPointerModeHandlers.AutomaticMode>(accelerator, CuBlasVersion))
{
// Automatic transfer to host
float output = blas.Nrm2(buf);
// Automatic transfer to device
blas.Nrm2(buf, buf2);
}
}
}
}
}
public static float[] RunOddEvenSort2(float[] a)
{
int N = a.Length;
bool evenArr = (N % 2) == 0 ? true : false;
//Create context and accelerator
var gpu = new CudaAccelerator(new Context());
//Create typed launcher
var oddEvenKernel = gpu.LoadAutoGroupedStreamKernel <
Index1,
ArrayView <float>,
VariableView <byte>,
int,
bool>(OddEvenSort2);
//Allocate memory
MemoryBuffer <float> d_a = gpu.Allocate <float>(N);
MemoryBuffer <byte> d_stopFlag = gpu.AllocateZero <byte>(1);
d_a.CopyFrom(a, 0, Index1.Zero, N);
//Run kernel
oddEvenKernel(N / 2, d_a, d_stopFlag.View.GetVariableView(0), N, evenArr);
gpu.Synchronize();
return(d_a.GetAsArray());
}
public static float[] RunFloydWarshall(float[][] a, int N, ref Stopwatch sw)
{
//Create context and accelerator
var gpu = new CudaAccelerator(new Context());
//Create typed launcher
var floydWarshallKernel = gpu.LoadAutoGroupedStreamKernel <
Index1,
int,
ArrayView <float>,
int>(FloydWarshall);
//Allocate memory
var bufSize = N * N;
MemoryBuffer <float> d_graphMinDist = gpu.Allocate <float>(bufSize);
d_graphMinDist.CopyFrom(FlatternArr(a), 0, Index1.Zero, bufSize);
sw.Restart();
for (int k = 0; k < N; k++)
{
floydWarshallKernel(bufSize, k, d_graphMinDist, N);
gpu.Synchronize();
}
sw.Stop();
return(d_graphMinDist.GetAsArray());
}
public static void IlGpu(CudaAccelerator gpu, Real[] matrix, Real[] vector, int m, int n)
{
using (var cudaMatrix = gpu.Allocate(matrix))
using (var cudaVector = gpu.Allocate(vector))
{
var timer = Stopwatch.StartNew();
var gridSizeX = Util.DivUp(n, 32);
var gridSizeY = Util.DivUp(m, 8);
var lp = ((gridSizeX, gridSizeY, 1), (32, 8));
gpu.Launch(IlGpuKernel, gpu.DefaultStream, lp, cudaMatrix.View, cudaVector.View, m, n);
gpu.Synchronize();
Util.PrintPerformance(timer, "AddVector.IlGpu", 3, m, n);
cudaMatrix.CopyTo(matrix, 0, 0, matrix.Length);
}
}
public static float[] RunMatrixMulShared(float[][] a, float[][] b, int N, ref Stopwatch sw)
{
//Create context and accelerator
var gpu = new CudaAccelerator(new Context());
//Create typed launcher
var matrixMulKernelShared = gpu.LoadStreamKernel <
ArrayView <float>,
ArrayView <float>,
ArrayView <float>,
int>(MatrixMulShared);
//Allocate memory
var buffSize = N * N;
MemoryBuffer <float> d_a = gpu.Allocate <float>(buffSize);
MemoryBuffer <float> d_b = gpu.Allocate <float>(buffSize);
MemoryBuffer <float> d_c = gpu.Allocate <float>(buffSize);
d_a.CopyFrom(FlatternArr(a), 0, Index1.Zero, buffSize);
d_b.CopyFrom(FlatternArr(b), 0, Index1.Zero, buffSize);
//Groups per grid dimension
int GrPerDim = (int)Math.Ceiling((float)N / groupSize);
KernelConfig dimension = (
new Index2(GrPerDim, GrPerDim), // Number of groups
new Index2(groupSize, groupSize)); // Group size (thread count in group)
sw.Restart();
matrixMulKernelShared(dimension, d_a.View, d_b.View, d_c.View, N);
// Wait for the kernel to finish...
gpu.Synchronize();
sw.Stop();
var c = d_c.GetAsArray();
return(c);
}
public static float[] RunOddEvenSort(float[] a, ref Stopwatch sw)
{
int N = a.Length;
bool evenArr = (N % 2) == 0 ? true : false;
bool stopFlag = false;
bool iterationEven = true;
//Create context and accelerator
var gpu = new CudaAccelerator(new Context());
//Create typed launcher
var oddEvenKernel = gpu.LoadAutoGroupedStreamKernel <
Index1,
ArrayView <float>,
VariableView <byte>,
bool,
int,
bool>(OddEvenSort);
//Allocate memory
MemoryBuffer <float> d_a = gpu.Allocate <float>(N);
MemoryBuffer <byte> d_stopFlag = gpu.AllocateZero <byte>(1);
d_a.CopyFrom(a, 0, Index1.Zero, N);
sw.Restart();
//Run kernel
byte[] zero_val = new byte[1];
zero_val[0] = 0;
while (true)
{
if (stopFlag)
{
break;
}
stopFlag = true;
d_stopFlag.CopyFrom(zero_val, 0, 0, 1);
oddEvenKernel(N / 2, d_a, d_stopFlag.View.GetVariableView(), iterationEven, N, evenArr);
gpu.Synchronize();
if (d_stopFlag.GetAsArray()[0] > 0)
{
stopFlag = false;
}
iterationEven = !iterationEven;
}
sw.Stop();
return(d_a.GetAsArray());
}
public override void Init()
{
GeneratePTX(); // alternative approach through this?
context = new Context();
accelerator = new CudaAccelerator(context);
var methodInfo = typeof(Impl_ILGPU).GetMethod(nameof(MyKernel), BindingFlags.Public | BindingFlags.Static);
myKernel = accelerator.LoadAutoGroupedStreamKernel <Index,
ArrayView <byte>,
ArrayView <double>,
ArrayView <int>,
ArrayView <int>,
ArrayView <double>,
ArrayView <byte>,
int
>(MyKernel);
// Allocate some memory
input1_dev = accelerator.Allocate <int>(DataGenerator.In1.Length);
input2_dev = accelerator.Allocate <int>(DataGenerator.In2.Length);
input3_dev = accelerator.Allocate <double>(DataGenerator.In3.Length);
input4_dev = accelerator.Allocate <byte>(DataGenerator.In4_3_bytes.Length);
// init output parameters
result_dev = accelerator.Allocate <byte>(resultsBytes.Length);
resultCalc_dev = accelerator.Allocate <double>(calculatables.Length);
input1_dev.CopyFrom(DataGenerator.In1, 0, 0, DataGenerator.In1.Length);
input2_dev.CopyFrom(DataGenerator.In2, 0, 0, DataGenerator.In2.Length);
input3_dev.CopyFrom(DataGenerator.In3, 0, 0, DataGenerator.In3.Length);
input4_dev.CopyFrom(DataGenerator.In4_3_bytes, 0, 0, DataGenerator.In4_3_bytes.Length);
}
public static void IlGpu(
CudaAccelerator gpu,
Real[] mSquaredDistances,
Real[] mCoordinates,
int c,
int n)
{
using var cudaSquaredDistance = gpu.Allocate(mSquaredDistances);
using var cudaCoordinates = gpu.Allocate(mCoordinates);
var timer = Stopwatch.StartNew();
const int blockSize = 128;
var gridSize = Util.DivUp(n * n, blockSize);
var lp = (gridSize, blockSize);
gpu.Launch(IlGpuKernel, gpu.DefaultStream, lp, cudaSquaredDistance.View, cudaCoordinates.View, c, n);
gpu.Synchronize();
Util.PrintPerformance(timer, "SquaredDistance.IlGpu", n, c, n);
cudaSquaredDistance.CopyTo(mSquaredDistances, 0, 0, mSquaredDistances.Length);
}
private static void IlGpuOptimisedImpl(
CudaAccelerator gpu,
Real[] mSquaredDistances,
Real[] mCoordinates,
int c,
int n,
string name,
Action <ArrayView2D <Real>, ArrayView <Real>, SpecializedValue <int>, SpecializedValue <int>, int> kernelFunc)
{
using var cudaSquaredDistance = gpu.Allocate <Real>(n, n);
using var cudaCoordinates = gpu.Allocate(mCoordinates);
var timer = Stopwatch.StartNew();
const int blockSize = 128;
var gridSize = Util.DivUp(n, blockSize);
var lp = ((gridSize, gridSize, 1), (blockSize, 1, 1));
gpu.Launch(kernelFunc, gpu.DefaultStream, lp, cudaSquaredDistance.View, cudaCoordinates.View, SpecializedValue.New(blockSize), SpecializedValue.New(c), n);
gpu.Synchronize();
Util.PrintPerformance(timer, name, n, c, n);
cudaSquaredDistance.CopyTo(mSquaredDistances, (0, 0), 0, (n, n));
}
public static void Main()
{
using Context context = new Context();
context.EnableAlgorithms();
using Accelerator device = new CudaAccelerator(context);
int width = 1920;
int height = 1080;
byte[] h_bitmapData = new byte[width * height * 3];
using MemoryBuffer2D <Vec3> canvasData = device.Allocate <Vec3>(width, height);
using MemoryBuffer <byte> d_bitmapData = device.Allocate <byte>(width * height * 3);
CanvasData c = new CanvasData(canvasData, d_bitmapData, width, height);
// pos // look at // up
Camera camera = new Camera(new Vec3(0, 50, -100), new Vec3(0, 0, 0), new Vec3(0, -1, 0), width, height, 40f);
WorldData world = new WorldData(device);
//world.loadMesh(new Vec3(10, 0, 0), "./Assets/defaultcube.obj");
world.loadMesh(new Vec3(0, 0, 0), "./Assets/cat.obj");
var frameBufferToBitmap = device.LoadAutoGroupedStreamKernel <Index2, CanvasData>(CanvasData.CanvasToBitmap);
var RTMethod = device.LoadAutoGroupedStreamKernel <Index2, CanvasData, dWorldBuffer, Camera>(PerPixelRayIntersectionMethod);
//do rasterization here
Stopwatch timer = new Stopwatch();
timer.Start();
RTMethod(new Index2(width, height), c, world.getDeviceWorldBuffer(), camera);
frameBufferToBitmap(canvasData.Extent, c);
device.Synchronize();
d_bitmapData.CopyTo(h_bitmapData, 0, 0, d_bitmapData.Extent);
timer.Stop();
Console.WriteLine("Rendered in: " + timer.Elapsed);
//bitmap magic that ignores striding be careful with some
using Bitmap b = new Bitmap(width, height, width * 3, PixelFormat.Format24bppRgb, Marshal.UnsafeAddrOfPinnedArrayElement(h_bitmapData, 0));
b.Save("out.bmp");
Process.Start("cmd.exe", "/c out.bmp");
}
private static void Performance()
{
using (var context = new Context())
{
using (var accelerator = new CudaAccelerator(context))
{
using (var b = accelerator.CreateBackend())
{
using (var c = accelerator.Context.CreateCompileUnit(b))
{
var method = typeof(Program).GetMethod("MathKernel", BindingFlags.Static | BindingFlags.Public);
var compiled = b.Compile(c, method);
var kernel = accelerator.LoadAutoGroupedStreamKernel<Index2, ArrayView2D<float>>(MathKernel);
//var kernel = accelerator.LoadAutoGroupedKernel(compiled);
int size = 100000;
var W = new[] { 50 };
var H = new[] { 50 };
for (int n = 0; n < W.Length; n++)
{
for (int m = 0; m < H.Length; m++)
{
int x = W[n];
int y = H[m];
Console.WriteLine($"\n\nW {x}, H {y} \n\n");
//var watch = Stopwatch.StartNew();
//for (int k = 0; k < size; k++)
//{
// var v = new float[x, y];
// for (int i = 0; i < x; i++)
// {
// for (int j = 0; j < y; j++)
// {
// v[i, j] = (float)Math.Sqrt(i * j);
// }
// }
//}
//watch.Stop();
//Console.WriteLine($"\n\nElapsed CPU Time Linear: {watch.ElapsedMilliseconds}ms\n");
//GC.Collect();
//
//watch = Stopwatch.StartNew();
//Parallel.For(0, size, k =>
//{
// var v = new float[x, y];
// Parallel.For(0, x, i =>
// {
// Parallel.For(0, y, j =>
// {
// v[i, j] = (float)Math.Sqrt(i * j);
// });
// });
//});
//watch.Stop();
//Console.WriteLine($"Elapsed CPU Time Parallel: {watch.ElapsedMilliseconds}ms\n\n");
//GC.Collect();
//var watch = Stopwatch.StartNew();
//for (int k = 0; k < size; k++)
//{
// var idx = new Index2(x, y);
// var buffer = accelerator.Allocate<float>(idx);
// kernel(idx, buffer.View);
// accelerator.Synchronize();
// buffer.Dispose();
//}
//watch.Stop();
//Console.WriteLine($"\n\nElapsed GPU Time Linear: {watch.ElapsedMilliseconds}ms\n");
//GC.Collect();
var kn = Enumerable.Repeat(accelerator.LoadAutoGroupedStreamKernel<Index2, ArrayView2D<float>>(MathKernel), size).ToList();
var watch = Stopwatch.StartNew();
Parallel.For(0, size, k =>
{
var idx = new Index2(x, y);
var buffer = accelerator.Allocate<float>(idx);
//kn[k](idx, buffer.View);
//kernel.Launch(idx, buffer.View);
kernel(idx, buffer.View);
accelerator.Synchronize();
buffer.Dispose();
});
watch.Stop();
Console.WriteLine($"Elapsed GPU Time Parallel: {watch.ElapsedMilliseconds}ms\n\n");
GC.Collect();
}
}
}
}
}
}
}
public void ProccessOld()
{
// Create the required ILGPU context
using (var context = new Context())
{
/*
* using (var accelerator = new CPUAccelerator(context))
* {
* // accelerator.LoadAutoGroupedStreamKernel creates a typed launcher
* // that implicitly uses the default accelerator stream.
* // In order to create a launcher that receives a custom accelerator stream
* // use: accelerator.LoadAutoGroupedKernel<Index, ArrayView<int> int>(...)
* var myKernel = accelerator.LoadAutoGroupedStreamKernel<Index, ArrayView<int>, int>(MyKernel2);
*
* // Allocate some memory
* using (var buffer = accelerator.Allocate<int>(1024))
* {
* // Launch buffer.Length many threads and pass a view to buffer
* myKernel(buffer.Length, buffer.View, 42);
*
* // Wait for the kernel to finish...
* accelerator.Synchronize();
*
* // Resolve data
* var data = buffer.GetAsArray();
* // ...
* }
* }*/
using (var accelerator = new CudaAccelerator(context)) // test with CPUAccelerator
{
var methodInfo = typeof(Impl_ILGPU).GetMethod(nameof(MyKernel), BindingFlags.Public | BindingFlags.Static);
var myKernel = accelerator.LoadAutoGroupedStreamKernel <Index,
ArrayView <byte>,
ArrayView <double>,
ArrayView <int>,
ArrayView <int>,
ArrayView <double>,
ArrayView <byte>,
int
>(MyKernel);
/*
* var myKernel = accelerator.LoadAutoGroupedStreamKernel<Action<Index,
* ArrayView<byte>,
* ArrayView<int>,
* ArrayView<int>,
* ArrayView<double>,
* ArrayView2D<byte>>>(methodInfo);*/
// Allocate some memory
var input1_dev = accelerator.Allocate <int>(DataGenerator.In1.Length);
var input2_dev = accelerator.Allocate <int>(DataGenerator.In2.Length);
var input3_dev = accelerator.Allocate <double>(DataGenerator.In3.Length);
//var input4_dev = accelerator.Allocate<byte>(DataGenerator.In4_2.GetLength(0), DataGenerator.In4_2.GetLength(1));
var input4_dev = accelerator.Allocate <byte>(DataGenerator.In4_3_bytes.Length);
// init output parameters
var result_dev = accelerator.Allocate <byte>(resultsBytes.Length);
var resultCalc_dev = accelerator.Allocate <double>(calculatables.Length);
input1_dev.CopyFrom(DataGenerator.In1, 0, 0, DataGenerator.In1.Length);
input2_dev.CopyFrom(DataGenerator.In2, 0, 0, DataGenerator.In2.Length);
input3_dev.CopyFrom(DataGenerator.In3, 0, 0, DataGenerator.In3.Length);
//input4_dev.CopyFrom(DataFeeder.In4_2_bytes, new Index2(), new Index2(DataFeeder.In4_2_bytes.GetLength(0), 0), new Index2(1, 2));
//input4_dev.CopyFrom(DataGenerator.In4_2_bytes, Index2.Zero, Index2.Zero, input4_dev.Extent);
input4_dev.CopyFrom(DataGenerator.In4_3_bytes, 0, 0, DataGenerator.In4_3_bytes.Length);
myKernel(input1_dev.Length, result_dev.View, resultCalc_dev.View, input1_dev.View, input2_dev.View, input3_dev.View, input4_dev.View, DataGenerator.Width);
// Wait for the kernel to finish...
accelerator.Synchronize();
// Resolve data
resultsBytes = result_dev.GetAsArray();
calculatables = resultCalc_dev.GetAsArray();
//d_in1.Dispose();
//d_in1 = null;
/*
* var kernelWithDefaultStream = accelerator.LoadAutoGroupedStreamKernel<
* Index,
* ArrayView<bool>,
* ArrayView<int>,
* ArrayView<int>,
* ArrayView<double>,
* ArrayView2D<bool>
* >(MyKernel);
*
* kernelWithDefaultStream(buffer.Extent, buffer.View, 1);
*/
// Launch buffer.Length many threads and pass a view to buffer
//myKernel(d_in1.Length, d_in1.View, 42);
// Wait for the kernel to finish...
//accelerator.Synchronize();
// Resolve data
//var data = buffer.GetAsArray();
// ...
}
}
}
