Exemplo n.º 1
0
        static void CleanupResources()
        {
            // Free device memory
            if (d_A != null)
            {
                d_A.Dispose();
            }

            if (d_B != null)
            {
                d_B.Dispose();
            }

            if (d_C != null)
            {
                d_C.Dispose();
            }

            if (ctx != null)
            {
                ctx.Dispose();
            }

            // Free host memory
            // We have a GC for that :-)
        }
Exemplo n.º 2
0
 public void Dispose()
 {
     baseImageBuffer.Dispose();
     nextImageBuffer.Dispose();
     pointsBuffer.Dispose();
     ctx.Dispose();
 }
Exemplo n.º 3
0
        public void RunExperiment(Grammar grm, bool nvrtc = true, bool remote = false)
        {
            Initialize(grm);  ///                                      ---  (1)  gp, grammar, population, individual


            // Evolution of generations
            for (int gen = 0; gen < GENCOUNT; gen++)
            {
                CreateSourceCodes(PARALLELISM_LEVEL); ///    ---  (2)  create source

                PTXcompile(nvrtc, remote);            ///                     ---  (3) ptx compile

                JITcompile();                         ///                     ---  (4) JIT compile

                tic();

                CreateKernelObjects();      ///                     ---

                LaunchKernels();            ///                     ---  (5)  launch kernel

                WaitCompleteAndReadBack();  ///                     ---



                GPoperations();             ///                     ---  (6) gp operations: selection, XO, mutation

                SampleCollector.Collect("other", toc());
            }
            ctx.Dispose();
        }
Exemplo n.º 4
0
 void OnDestroy()
 {
     d_idata.Dispose();
     d_odata.Dispose();
     d_result_data.Dispose();
     ctx.Dispose();
 }
Exemplo n.º 5
0
    private void CleanupResources()
    {
        // Free device memory
        if (d_A != null)
        {
            d_A?.Dispose();
        }
        if (d_B != null)
        {
            d_B?.Dispose();
        }
        //   d_C?.Dispose();

        if (C != null)
        {
            C?.Dispose();
        }
        if (ctx != null)
        {
            ctx?.Dispose();
        }

        // Free host memory
        // We have a GC for that :-)
    }
Exemplo n.º 6
0
        static void CleanupResources()
        {
            // Free device memory
            if (dev_v0 != null)
            {
                dev_v0.Dispose();
            }

            if (dev_v1 != null)
            {
                dev_v1.Dispose();
            }

            if (dev_v2 != null)
            {
                dev_v2.Dispose();
            }

            if (dev_da != null)
            {
                dev_da.Dispose();
            }

            if (dev_db != null)
            {
                dev_db.Dispose();
            }

            if (dev_dc != null)
            {
                dev_dc.Dispose();
            }

            if (dev_dOut != null)
            {
                dev_dOut.Dispose();
            }

            if (dev_height != null)
            {
                dev_height.Dispose();
            }

            if (dev_width != null)
            {
                dev_width.Dispose();
            }

            if (ctx != null)
            {
                ctx.Dispose();
            }

            // Free host memory
            // We have a GC for that :-)
        }
Exemplo n.º 7
0
 public virtual void Dispose()
 {
     DevicePositions.Dispose();
     DevicePersonalBestValues.Dispose();
     DeviceVelocities.Dispose();
     DevicePersonalBests.Dispose();
     _phis1.Dispose();
     _phis2.Dispose();
     Ctx.Dispose();
 }
Exemplo n.º 8
0
 protected virtual void Dispose(bool disposing)
 {
     if (disposing && !_disposed)
     {
         _blas.Dispose();
         _cuda.Dispose();
         //if(_solver.IsValueCreated)
         //    _solver.Value.Dispose();
         _numerics.Dispose();
         _disposed = true;
     }
 }
        public void DisposeCuda()
        {
            CudaContext context = Context;

            if (context != null)
            {
                Context = null;
                try {
                    context.Dispose();
                } catch {
                    // if this fails, it will probably just mask the actual error further up the stack (e.g. OOM)
                }
            }
        }
Exemplo n.º 10
0
        protected virtual void Dispose(bool disposing)
        {
            if (!isDisposed)
            {
                if (disposing)
                {
                }

                prefixScan.Dispose();
                // Unloading every single kernel will cause an error.
                context.UnloadModule(module);
                context.Dispose();
            }

            isDisposed = true;
        }
Exemplo n.º 11
0
        //Clean up before closing
        private void Form1_FormClosing(object sender, FormClosingEventArgs e)
        {
            isRunning = false;
            isInit    = false;
            cuda_vbo_resource.Dispose();
            texref.Dispose();
            dvfield.Dispose();
            vxfield.Dispose();
            vyfield.Dispose();

            planc2r.Dispose();
            planr2c.Dispose();

            GL.BindBuffer(BufferTarget.ArrayBuffer, 0);
            GL.DeleteBuffers(1, ref vbo);

            stopwatch.Dispose();
            ctx.Dispose();
        }
Exemplo n.º 12
0
        static void Main(string[] args)
        {
            try
            {
                if (args.Length == 1 && args[0].ToLower().Contains("fidelity"))
                {
                    string[] fseg = args[0].Split(':');
                    deviceID = int.Parse(fseg[1]);
                    nonce    = Int64.Parse(fseg[2]) - 1;
                    range    = int.Parse(fseg[3]);
                    QTEST    = true;
                }
                else
                {
                    if (args.Length > 0)
                    {
                        deviceID = int.Parse(args[0]);
                    }
                }
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Device ID parse error: " + ex.Message);
            }

            try
            {
                if (args.Length > 0)
                {
                    deviceID = int.Parse(args[0]);
                }
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Device ID parse error");
            }

            try
            {
                if (args.Length > 1)
                {
                    port = int.Parse(args[1]);
                    Comms.ConnectToMaster(port);
                }
                else
                {
                    TEST = true;
                    Logger.CopyToConsole = true;
                    CGraph.ShowCycles    = true;
                }
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Master connection error");
            }

            try
            {
                if (args.Length > 3)
                {
                    gpuCount = int.Parse(args[3]);
                    fastCuda = gpuCount <= (Environment.ProcessorCount / 2);
                    if (fastCuda)
                    {
                        Logger.Log(LogLevel.Info, "Using single GPU blocking mode");
                    }
                }
            }
            catch
            {
            }

            if (TEST)
            {
                currentJob = nextJob = new Job()
                {
                    jobID     = 0,
                    k0        = 0xf4956dc403730b01L,
                    k1        = 0xe6d45de39c2a5a3eL,
                    k2        = 0xcbf626a8afee35f6L,
                    k3        = 0x4307b94b1a0c9980L,
                    pre_pow   = TestPrePow,
                    timestamp = DateTime.Now
                };
            }
            else
            {
                currentJob = nextJob = new Job()
                {
                    jobID     = 0,
                    k0        = 0xf4956dc403730b01L,
                    k1        = 0xe6d45de39c2a5a3eL,
                    k2        = 0xcbf626a8afee35f6L,
                    k3        = 0x4307b94b1a0c9980L,
                    pre_pow   = TestPrePow,
                    timestamp = DateTime.Now
                };

                if (!Comms.IsConnected())
                {
                    Console.WriteLine("Master connection failed, aborting");
                    Logger.Log(LogLevel.Error, "No master connection, exitting!");
                    return;
                }

                if (deviceID < 0)
                {
                    int devCnt             = CudaContext.GetDeviceCount();
                    GpuDevicesMessage gpum = new GpuDevicesMessage()
                    {
                        devices = new List <GpuDevice>(devCnt)
                    };
                    for (int i = 0; i < devCnt; i++)
                    {
                        string name = CudaContext.GetDeviceName(i);
                        var    info = CudaContext.GetDeviceInfo(i);
                        gpum.devices.Add(new GpuDevice()
                        {
                            deviceID = i, name = name, memory = info.TotalGlobalMemory
                        });
                    }
                    //Console.WriteLine(devCnt);
                    Comms.gpuMsg = gpum;
                    Comms.SetEvent();
                    //Console.WriteLine("event fired");
                    Task.Delay(1000).Wait();
                    //Console.WriteLine("closing");
                    Comms.Close();
                    return;
                }
            }

            try
            {
                var assembly       = Assembly.GetEntryAssembly();
                var resourceStream = assembly.GetManifestResourceStream("CudaSolver.kernel_x64.ptx");
                ctx = new CudaContext(deviceID, /*!fastCuda ? (CUCtxFlags.BlockingSync | CUCtxFlags.MapHost) :*/ CUCtxFlags.MapHost);
                string pow = new StreamReader(resourceStream).ReadToEnd();

                //pow = File.ReadAllText(@"kernel_x64.ptx");

                Turing = ctx.GetDeviceInfo().MaxSharedMemoryPerMultiprocessor == 65536;

                using (var s = GenerateStreamFromString(pow))
                {
                    if (!Turing)
                    {
                        meanSeedA = ctx.LoadKernelPTX(s, "FluffySeed4K", new CUJITOption[] { CUJITOption.MaxRegisters }, new object[] { (uint)40 });
                        meanSeedA.BlockDimensions = 512;
                        meanSeedA.GridDimensions  = 1024;
                        meanSeedA.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                        meanRound = ctx.LoadKernelPTX(s, "FluffyRound_A2", new CUJITOption[] { CUJITOption.MaxRegisters }, new object[] { (uint)40 });
                        meanRound.BlockDimensions = 512;
                        meanRound.GridDimensions  = 4096;
                        meanRound.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                        meanRound_4 = ctx.LoadKernelPTX(s, "FluffyRound_A1", new CUJITOption[] { CUJITOption.MaxRegisters }, new object[] { (uint)32 });
                        meanRound_4.BlockDimensions = 1024;
                        meanRound_4.GridDimensions  = 1024;
                        meanRound_4.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                        meanRoundJoin = ctx.LoadKernelPTX(s, "FluffyRound_A3", new CUJITOption[] { CUJITOption.MaxRegisters }, new object[] { (uint)32 });
                        meanRoundJoin.BlockDimensions = 1024;
                        meanRoundJoin.GridDimensions  = 4096;
                        meanRoundJoin.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                        meanTail = ctx.LoadKernelPTX(s, "FluffyTail");
                        meanTail.BlockDimensions = 1024;
                        meanTail.GridDimensions  = 4096;
                        meanTail.PreferredSharedMemoryCarveout = CUshared_carveout.MaxL1;

                        meanRecover = ctx.LoadKernelPTX(s, "FluffyRecovery");
                        meanRecover.BlockDimensions = 256;
                        meanRecover.GridDimensions  = 2048;
                        meanRecover.PreferredSharedMemoryCarveout = CUshared_carveout.MaxL1;
                    }
                    else
                    {
                        meanSeedA = ctx.LoadKernelPTX(s, "FluffySeed4K", new CUJITOption[] { CUJITOption.MaxRegisters }, new object[] { (uint)64 });
                        meanSeedA.BlockDimensions = 512;
                        meanSeedA.GridDimensions  = 1024;
                        meanSeedA.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                        meanRound = ctx.LoadKernelPTX(s, "FluffyRound_C2", new CUJITOption[] { CUJITOption.MaxRegisters }, new object[] { (uint)32 });
                        meanRound.BlockDimensions = 1024;
                        meanRound.GridDimensions  = 4096;
                        meanRound.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                        meanRound_4 = ctx.LoadKernelPTX(s, "FluffyRound_C1", new CUJITOption[] { CUJITOption.MaxRegisters }, new object[] { (uint)64 });
                        meanRound_4.BlockDimensions = 1024;
                        meanRound_4.GridDimensions  = 1024;
                        meanRound_4.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                        meanRoundJoin = ctx.LoadKernelPTX(s, "FluffyRound_C3", new CUJITOption[] { CUJITOption.MaxRegisters }, new object[] { (uint)32 });
                        meanRoundJoin.BlockDimensions = 1024;
                        meanRoundJoin.GridDimensions  = 4096;
                        meanRoundJoin.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                        meanTail = ctx.LoadKernelPTX(s, "FluffyTail");
                        meanTail.BlockDimensions = 1024;
                        meanTail.GridDimensions  = 4096;
                        meanTail.PreferredSharedMemoryCarveout = CUshared_carveout.MaxL1;

                        meanRecover = ctx.LoadKernelPTX(s, "FluffyRecovery");
                        meanRecover.BlockDimensions = 256;
                        meanRecover.GridDimensions  = 2048;
                        meanRecover.PreferredSharedMemoryCarveout = CUshared_carveout.MaxL1;
                    }
                }
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Unable to create kernels: " + ex.Message);
                Task.Delay(500).Wait();
                Comms.Close();
                return;
            }

            try
            {
                d_buffer    = new CudaDeviceVariable <ulong>(BUFFER_SIZE_U32 * (temp ? 8 : 1));
                d_bufferMid = new CudaDeviceVariable <ulong>(d_buffer.DevicePointer + (BUFFER_SIZE_B * 2));
                d_bufferB   = new CudaDeviceVariable <ulong>(d_buffer.DevicePointer + (BUFFER_SIZE_B * 8));

                d_indexesA = new CudaDeviceVariable <uint>(INDEX_SIZE);
                d_indexesB = new CudaDeviceVariable <uint>(INDEX_SIZE);
                d_aux      = new CudaDeviceVariable <uint>(512);

                Array.Clear(h_indexesA, 0, h_indexesA.Length);
                Array.Clear(h_indexesB, 0, h_indexesA.Length);

                d_indexesA = h_indexesA;
                d_indexesB = h_indexesB;

                streamPrimary = new CudaStream(CUStreamFlags.NonBlocking);
            }
            catch (Exception ex)
            {
                Task.Delay(200).Wait();
                Logger.Log(LogLevel.Error, $"Mem alloc exception. Out of video memory? {ctx.GetFreeDeviceMemorySize()} free");
                Task.Delay(500).Wait();
                Comms.Close();
                return;
            }

            try
            {
                AllocateHostMemory(true, ref h_a, ref hAligned_a, 1024 * 1024 * 32);
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Unable to create pinned memory.");
                Task.Delay(500).Wait();
                Comms.Close();
                return;
            }

            int loopCnt = 0;

            while (!Comms.IsTerminated)
            {
                try
                {
                    if (!TEST && (Comms.nextJob.pre_pow == null || Comms.nextJob.pre_pow == "" || Comms.nextJob.pre_pow == TestPrePow))
                    {
                        Logger.Log(LogLevel.Info, string.Format("Waiting for job...."));
                        Task.Delay(1000).Wait();
                        continue;
                    }

                    if (!TEST && ((currentJob.pre_pow != Comms.nextJob.pre_pow) || (currentJob.origin != Comms.nextJob.origin)))
                    {
                        currentJob           = Comms.nextJob;
                        currentJob.timestamp = DateTime.Now;
                    }

                    if (!TEST && (currentJob.timestamp.AddMinutes(30) < DateTime.Now) && Comms.lastIncoming.AddMinutes(30) < DateTime.Now)
                    {
                        Logger.Log(LogLevel.Info, string.Format("Job too old..."));
                        Task.Delay(1000).Wait();
                        continue;
                    }

                    // test runs only once
                    if (TEST && ++loopCnt >= range)
                    {
                        Comms.IsTerminated = true;
                    }

                    Solution s;
                    while (graphSolutions.TryDequeue(out s))
                    {
                        meanRecover.SetConstantVariable <ulong>("recovery", s.GetUlongEdges());
                        d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                        meanRecover.RunAsync(streamPrimary.Stream, s.job.k0, s.job.k1, s.job.k2, s.job.k3, d_indexesB.DevicePointer);
                        streamPrimary.Synchronize();
                        s.nonces = new uint[32];
                        d_indexesB.CopyToHost(s.nonces, 0, 0, 32 * 4);
                        s.nonces = s.nonces.OrderBy(n => n).ToArray();
                        //fidelity = (32-cycles_found / graphs_searched) * 32
                        solutions++;
                        s.fidelity = ((double)solutions / (double)trims) * 32.0;
                        //Console.WriteLine(s.fidelity.ToString("0.000"));
                        if (Comms.IsConnected())
                        {
                            Comms.graphSolutionsOut.Enqueue(s);
                            Comms.SetEvent();
                        }
                        if (QTEST)
                        {
                            Console.ForegroundColor = ConsoleColor.Red;
                            Console.WriteLine($"Solution for nonce {s.job.nonce}: {string.Join(' ', s.nonces)}");
                            Console.ResetColor();
                        }
                    }

                    if (QTEST)
                    {
                        currentJob = currentJob.NextSequential(ref nonce);
                        Console.WriteLine($"Nonce: {nonce} K0: {currentJob.k0:X} K1: {currentJob.k1:X} K2: {currentJob.k2:X} K3: {currentJob.k3:X}");
                    }
                    else
                    {
                        currentJob = currentJob.Next();
                    }

                    Logger.Log(LogLevel.Debug, string.Format("GPU NV{4}:Trimming #{4}: {0} {1} {2} {3}", currentJob.k0, currentJob.k1, currentJob.k2, currentJob.k3, currentJob.jobID, deviceID));

                    timer.Restart();

                    d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                    d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                    d_aux.MemsetAsync(0, streamPrimary.Stream);

                    meanSeedA.RunAsync(streamPrimary.Stream, currentJob.k0, currentJob.k1, currentJob.k2, currentJob.k3, d_bufferMid.DevicePointer, d_indexesB.DevicePointer, 0);
                    meanSeedA.RunAsync(streamPrimary.Stream, currentJob.k0, currentJob.k1, currentJob.k2, currentJob.k3, d_bufferMid.DevicePointer + ((BUFFER_SIZE_A * 8) / 4 / 4) * 1, d_indexesB.DevicePointer + (4096 * 4), EDGE_SEG);
                    meanSeedA.RunAsync(streamPrimary.Stream, currentJob.k0, currentJob.k1, currentJob.k2, currentJob.k3, d_bufferMid.DevicePointer + ((BUFFER_SIZE_A * 8) / 4 / 4) * 2, d_indexesB.DevicePointer + (4096 * 8), EDGE_SEG * 2);
                    meanSeedA.RunAsync(streamPrimary.Stream, currentJob.k0, currentJob.k1, currentJob.k2, currentJob.k3, d_bufferMid.DevicePointer + ((BUFFER_SIZE_A * 8) / 4 / 4) * 3, d_indexesB.DevicePointer + (4096 * 12), EDGE_SEG * 3);

                    meanRound_4.RunAsync(streamPrimary.Stream, d_bufferMid.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_A / 4, DUCK_EDGES_B / 4, 0);
                    meanRound_4.RunAsync(streamPrimary.Stream, d_bufferMid.DevicePointer, d_buffer.DevicePointer + ((BUFFER_SIZE_B * 8) / 4) * 1, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_A / 4, DUCK_EDGES_B / 4, 1024);
                    meanRound_4.RunAsync(streamPrimary.Stream, d_bufferMid.DevicePointer, d_buffer.DevicePointer + ((BUFFER_SIZE_B * 8) / 4) * 2, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_A / 4, DUCK_EDGES_B / 4, 2048);
                    meanRound_4.RunAsync(streamPrimary.Stream, d_bufferMid.DevicePointer, d_buffer.DevicePointer + ((BUFFER_SIZE_B * 8) / 4) * 3, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_A / 4, DUCK_EDGES_B / 4, 3072);


                    //streamPrimary.Synchronize();
                    //h_indexesA = d_indexesA;
                    //h_indexesB = d_indexesB;
                    //var sumA = h_indexesA.Sum(e => e);
                    //var sumB = h_indexesB.Sum(e => e);
                    //streamPrimary.Synchronize();

                    d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                    meanRoundJoin.RunAsync(streamPrimary.Stream,
                                           d_buffer.DevicePointer,
                                           d_buffer.DevicePointer + ((BUFFER_SIZE_B * 8) / 4) * 1,
                                           d_buffer.DevicePointer + ((BUFFER_SIZE_B * 8) / 4) * 2,
                                           d_buffer.DevicePointer + ((BUFFER_SIZE_B * 8) / 4) * 3,
                                           d_bufferB.DevicePointer,
                                           d_indexesA.DevicePointer,
                                           d_indexesB.DevicePointer, DUCK_EDGES_B / 4, DUCK_EDGES_B / 2);

                    d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                    meanRound.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_B / 2, DUCK_EDGES_B / 2, 0, d_aux.DevicePointer);
                    d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                    meanRound.RunAsync(streamPrimary.Stream, d_buffer.DevicePointer, d_bufferB.DevicePointer, d_indexesA.DevicePointer, d_indexesB.DevicePointer, DUCK_EDGES_B / 2, DUCK_EDGES_B / 2, 1, d_aux.DevicePointer);
                    d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                    meanRound.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_B / 2, DUCK_EDGES_B / 2, 2, d_aux.DevicePointer);
                    d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                    meanRound.RunAsync(streamPrimary.Stream, d_buffer.DevicePointer, d_bufferB.DevicePointer, d_indexesA.DevicePointer, d_indexesB.DevicePointer, DUCK_EDGES_B / 2, DUCK_EDGES_B / 4, 3, d_aux.DevicePointer);

                    for (int i = 0; i < (TEST ? 80 : trimRounds); i++)
                    //for (int i = 0; i < 85; i++)
                    {
                        d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                        meanRound.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_B / 4, DUCK_EDGES_B / 4, i * 2 + 4, d_aux.DevicePointer);
                        d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                        meanRound.RunAsync(streamPrimary.Stream, d_buffer.DevicePointer, d_bufferB.DevicePointer, d_indexesA.DevicePointer, d_indexesB.DevicePointer, DUCK_EDGES_B / 4, DUCK_EDGES_B / 4, i * 2 + 5, d_aux.DevicePointer);
                    }

                    d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                    meanTail.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer);

                    Task.Delay((int)lastTrimMs).Wait();

                    streamPrimary.Synchronize();

                    uint[] count = new uint[2];
                    d_indexesA.CopyToHost(count, 0, 0, 8);

                    if (count[0] > 131071)
                    {
                        // trouble
                        count[0] = 131071;
                        // log
                    }

                    hAligned_a.AsyncCopyFromDevice(d_buffer.DevicePointer, 0, 0, count[0] * 8, streamPrimary.Stream);
                    streamPrimary.Synchronize();
                    System.Runtime.InteropServices.Marshal.Copy(hAligned_a.PinnedHostPointer, h_a, 0, ((int)count[0] * 8) / sizeof(int));

                    trims++;
                    timer.Stop();
                    lastTrimMs          = (long)Math.Min(Math.Max((float)timer.ElapsedMilliseconds * 0.9f, 50), 500);
                    currentJob.solvedAt = DateTime.Now;
                    currentJob.trimTime = timer.ElapsedMilliseconds;

                    //Console.WriteLine("Trimmed in {0}ms to {1} edges", timer.ElapsedMilliseconds, count[0]);
                    Logger.Log(LogLevel.Info, string.Format("GPU NV{2}:     Trimmed in {0}ms to {1} edges", timer.ElapsedMilliseconds, count[0], deviceID));


                    FinderBag.RunFinder(TEST, ref trims, count[0], h_a, currentJob, graphSolutions, timer);

                    if (trims % 50 == 0 && TEST)
                    {
                        Console.ForegroundColor = ConsoleColor.Green;
                        Console.WriteLine("SOLS: {0}/{1} - RATE: {2:F1}", solutions, trims, (float)trims / solutions);
                        Console.ResetColor();
                    }

                    /*
                     * if (TEST)
                     * {
                     *  //Console.WriteLine("Trimmed in {0}ms to {1} edges", timer.ElapsedMilliseconds, count[0]);
                     *
                     *  CGraph cg = FinderBag.GetFinder();
                     *  cg.SetEdges(h_a, (int)count[0]);
                     *  cg.SetHeader(currentJob);
                     *
                     *  //currentJob = currentJob.Next();
                     *
                     *  Task.Factory.StartNew(() =>
                     *     {
                     *         Stopwatch sw = new Stopwatch();
                     *         sw.Start();
                     *
                     *         if (count[0] < 131071)
                     *         {
                     *             try
                     *             {
                     *                 if (findersInFlight++ < 3)
                     *                 {
                     *                     Stopwatch cycleTime = new Stopwatch();
                     *                     cycleTime.Start();
                     *                     cg.FindSolutions(graphSolutions);
                     *                     cycleTime.Stop();
                     *                     AdjustTrims(cycleTime.ElapsedMilliseconds);
                     *                     //if (graphSolutions.Count > 0) solutions++;
                     *                 }
                     *                 else
                     *                     Logger.Log(LogLevel.Warning, "CPU overloaded!");
                     *             }
                     *             catch (Exception ex)
                     *             {
                     *                 Logger.Log(LogLevel.Error, "Cycle finder error" + ex.Message);
                     *             }
                     *             finally
                     *             {
                     *                 FinderBag.ReturnFinder(cg);
                     *                 findersInFlight--;
                     *             }
                     *         }
                     *
                     *         sw.Stop();
                     *
                     *         if (trims % 50 == 0)
                     *         {
                     *             Console.ForegroundColor = ConsoleColor.Green;
                     *             Console.WriteLine("SOLS: {0}/{1} - RATE: {2:F1}", solutions, trims, (float)trims/solutions );
                     *             Console.ResetColor();
                     *         }
                     *         //Console.WriteLine("Finder completed in {0}ms on {1} edges with {2} solution(s)", sw.ElapsedMilliseconds, count[0], graphSolutions.Count);
                     *         //Console.WriteLine("Duped edges: {0}", cg.dupes);
                     *         if (!QTEST)
                     *          Logger.Log(LogLevel.Info, string.Format("Finder completed in {0}ms on {1} edges with {2} solution(s) and {3} dupes", sw.ElapsedMilliseconds, count[0], graphSolutions.Count, cg.dupes));
                     *     });
                     *
                     *  //h_indexesA = d_indexesA;
                     *  //h_indexesB = d_indexesB;
                     *
                     *  //var sumA = h_indexesA.Sum(e => e);
                     *  //var sumB = h_indexesB.Sum(e => e);
                     *
                     *  ;
                     * }
                     * else
                     * {
                     *  CGraph cg = FinderBag.GetFinder();
                     *  cg.SetEdges(h_a, (int)count[0]);
                     *  cg.SetHeader(currentJob);
                     *
                     *  Task.Factory.StartNew(() =>
                     *  {
                     *      if (count[0] < 131071)
                     *      {
                     *          try
                     *          {
                     *              if (findersInFlight++ < 3)
                     *              {
                     *                  Stopwatch cycleTime = new Stopwatch();
                     *                  cycleTime.Start();
                     *                  cg.FindSolutions(graphSolutions);
                     *                  cycleTime.Stop();
                     *                  AdjustTrims(cycleTime.ElapsedMilliseconds);
                     *              }
                     *              else
                     *                  Logger.Log(LogLevel.Warning, "CPU overloaded!");
                     *          }
                     *          catch (Exception ex)
                     *          {
                     *              Logger.Log(LogLevel.Warning, "Cycle finder crashed: " + ex.Message);
                     *          }
                     *          finally
                     *          {
                     *              FinderBag.ReturnFinder(cg);
                     *              findersInFlight--;
                     *          }
                     *      }
                     *  });
                     * }
                     *
                     */
                }
                catch (Exception ex)
                {
                    Logger.Log(LogLevel.Error, "Critical error in main cuda loop " + ex.Message);
                    Task.Delay(500).Wait();
                    break;
                }
            }

            // clean up
            try
            {
                Task.Delay(500).Wait();

                Comms.Close();

                d_buffer.Dispose();
                d_indexesA.Dispose();
                d_indexesB.Dispose();
                d_aux.Dispose();

                streamPrimary.Dispose();
                streamSecondary.Dispose();

                hAligned_a.Dispose();

                if (ctx != null)
                {
                    ctx.Dispose();
                }
            }
            catch { }
        }
Exemplo n.º 13
0
        static void Main(string[] args)
        {
            int SIGNAL_SIZE        = 50;
            int FILTER_KERNEL_SIZE = 11;

            Console.WriteLine("[simpleCUFFT] is starting...");

            var assembly     = Assembly.GetExecutingAssembly();
            var resourceName = "simpleCUFFT.simpleCUFFTKernel.ptx";

            CudaContext ctx = new CudaContext(0);
            CudaKernel  ComplexPointwiseMulAndScale;

            string[] liste = assembly.GetManifestResourceNames();
            using (Stream stream = assembly.GetManifestResourceStream(resourceName))
            {
                ComplexPointwiseMulAndScale = ctx.LoadKernelPTX(stream, "ComplexPointwiseMulAndScale");
            }

            // Allocate host memory for the signal
            cuFloatComplex[] h_signal = new cuFloatComplex[SIGNAL_SIZE]; //we use cuFloatComplex for complex multiplaction in reference host code...

            Random rand = new Random(0);

            // Initialize the memory for the signal
            for (int i = 0; i < SIGNAL_SIZE; ++i)
            {
                h_signal[i].real = (float)rand.NextDouble();
                h_signal[i].imag = 0;
            }

            // Allocate host memory for the filter
            cuFloatComplex[] h_filter_kernel = new cuFloatComplex[FILTER_KERNEL_SIZE];

            // Initialize the memory for the filter
            for (int i = 0; i < FILTER_KERNEL_SIZE; ++i)
            {
                h_filter_kernel[i].real = (float)rand.NextDouble();
                h_filter_kernel[i].imag = 0;
            }

            // Pad signal and filter kernel
            cuFloatComplex[] h_padded_signal        = null;
            cuFloatComplex[] h_padded_filter_kernel = null;
            int new_size = PadData(h_signal, ref h_padded_signal, SIGNAL_SIZE,
                                   h_filter_kernel, ref h_padded_filter_kernel, FILTER_KERNEL_SIZE);
            int mem_size = (int)cuFloatComplex.SizeOf * new_size;


            // Allocate device memory for signal
            CudaDeviceVariable <cuFloatComplex> d_signal = new CudaDeviceVariable <cuFloatComplex>(new_size);

            // Copy host memory to device
            d_signal.CopyToDevice(h_padded_signal);

            // Allocate device memory for filter kernel
            CudaDeviceVariable <cuFloatComplex> d_filter_kernel = new CudaDeviceVariable <cuFloatComplex>(new_size);

            // Copy host memory to device
            d_filter_kernel.CopyToDevice(h_padded_filter_kernel);

            // CUFFT plan simple API
            CudaFFTPlan1D plan = new CudaFFTPlan1D(new_size, cufftType.C2C, 1);

            // Transform signal and kernel
            Console.WriteLine("Transforming signal cufftExecC2C");
            plan.Exec(d_signal.DevicePointer, TransformDirection.Forward);
            plan.Exec(d_filter_kernel.DevicePointer, TransformDirection.Forward);

            // Multiply the coefficients together and normalize the result
            Console.WriteLine("Launching ComplexPointwiseMulAndScale<<< >>>");
            ComplexPointwiseMulAndScale.BlockDimensions = 256;
            ComplexPointwiseMulAndScale.GridDimensions  = 32;
            ComplexPointwiseMulAndScale.Run(d_signal.DevicePointer, d_filter_kernel.DevicePointer, new_size, 1.0f / new_size);

            // Transform signal back
            Console.WriteLine("Transforming signal back cufftExecC2C");
            plan.Exec(d_signal.DevicePointer, TransformDirection.Inverse);

            // Copy device memory to host
            cuFloatComplex[] h_convolved_signal = d_signal;

            // Allocate host memory for the convolution result
            cuFloatComplex[] h_convolved_signal_ref = new cuFloatComplex[SIGNAL_SIZE];

            // Convolve on the host
            Convolve(h_signal, SIGNAL_SIZE,
                     h_filter_kernel, FILTER_KERNEL_SIZE,
                     h_convolved_signal_ref);

            // check result
            bool bTestResult = sdkCompareL2fe(h_convolved_signal_ref, h_convolved_signal, 1e-5f);

            //Destroy CUFFT context
            plan.Dispose();

            // cleanup memory
            d_filter_kernel.Dispose();
            d_signal.Dispose();
            ctx.Dispose();

            if (bTestResult)
            {
                Console.WriteLine("Test Passed");
            }
            else
            {
                Console.WriteLine("Test Failed");
            }
        }
Exemplo n.º 14
0
        static void Main(string[] args)
        {
            try
            {
                if (args.Length > 0)
                {
                    deviceID = int.Parse(args[0]);
                }
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Device ID parse error");
            }

            try
            {
                if (args.Length > 1)
                {
                    port = int.Parse(args[1]);
                    Comms.ConnectToMaster(port);
                }
                else
                {
                    TEST = true;
                    Logger.CopyToConsole = true;
                    CGraph.ShowCycles    = true;
                }
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Master connection error");
            }

            try
            {
                if (args.Length > 3)
                {
                    gpuCount = int.Parse(args[3]);
                    fastCuda = gpuCount <= (Environment.ProcessorCount / 2);
                    if (fastCuda)
                    {
                        Logger.Log(LogLevel.Info, "Using single GPU blocking mode");
                    }
                }
            }
            catch
            {
            }

            if (TEST)
            {
                currentJob = nextJob = new Job()
                {
                    jobID     = 0,
                    k0        = 0xf4956dc403730b01L,
                    k1        = 0xe6d45de39c2a5a3eL,
                    k2        = 0xcbf626a8afee35f6L,
                    k3        = 0x4307b94b1a0c9980L,
                    pre_pow   = TestPrePow,
                    timestamp = DateTime.Now
                };
            }
            else
            {
                currentJob = nextJob = new Job()
                {
                    jobID     = 0,
                    k0        = 0xf4956dc403730b01L,
                    k1        = 0xe6d45de39c2a5a3eL,
                    k2        = 0xcbf626a8afee35f6L,
                    k3        = 0x4307b94b1a0c9980L,
                    pre_pow   = TestPrePow,
                    timestamp = DateTime.Now
                };

                if (!Comms.IsConnected())
                {
                    Console.WriteLine("Master connection failed, aborting");
                    Logger.Log(LogLevel.Error, "No master connection, exitting!");
                    return;
                }

                if (deviceID < 0)
                {
                    int devCnt             = CudaContext.GetDeviceCount();
                    GpuDevicesMessage gpum = new GpuDevicesMessage()
                    {
                        devices = new List <GpuDevice>(devCnt)
                    };
                    for (int i = 0; i < devCnt; i++)
                    {
                        string name = CudaContext.GetDeviceName(i);
                        var    info = CudaContext.GetDeviceInfo(i);
                        gpum.devices.Add(new GpuDevice()
                        {
                            deviceID = i, name = name, memory = info.TotalGlobalMemory
                        });
                    }
                    //Console.WriteLine(devCnt);
                    Comms.gpuMsg = gpum;
                    Comms.SetEvent();
                    //Console.WriteLine("event fired");
                    Task.Delay(1000).Wait();
                    //Console.WriteLine("closing");
                    Comms.Close();
                    return;
                }
            }


            try
            {
                var assembly       = Assembly.GetEntryAssembly();
                var resourceStream = assembly.GetManifestResourceStream("CudaSolver.kernel_x64.ptx");
                ctx = new CudaContext(deviceID, !fastCuda ? (CUCtxFlags.BlockingSync | CUCtxFlags.MapHost) : CUCtxFlags.MapHost);

                meanSeedA = ctx.LoadKernelPTX(resourceStream, "FluffySeed2A");
                meanSeedA.BlockDimensions = 128;
                meanSeedA.GridDimensions  = 2048;
                meanSeedA.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                meanSeedB = ctx.LoadKernelPTX(resourceStream, "FluffySeed2B");
                meanSeedB.BlockDimensions = 128;
                meanSeedB.GridDimensions  = 2048;
                meanSeedB.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                meanSeedB_4 = ctx.LoadKernelPTX(resourceStream, "FluffySeed2B");
                meanSeedB_4.BlockDimensions = 128;
                meanSeedB_4.GridDimensions  = 1024;
                meanSeedB_4.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                meanRound = ctx.LoadKernelPTX(resourceStream, "FluffyRound");
                meanRound.BlockDimensions = 512;
                meanRound.GridDimensions  = 4096;
                meanRound.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                meanRound_2 = ctx.LoadKernelPTX(resourceStream, "FluffyRound");
                meanRound_2.BlockDimensions = 512;
                meanRound_2.GridDimensions  = 2048;
                meanRound_2.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                meanRoundJoin = ctx.LoadKernelPTX(resourceStream, "FluffyRound_J");
                meanRoundJoin.BlockDimensions = 512;
                meanRoundJoin.GridDimensions  = 4096;
                meanRoundJoin.PreferredSharedMemoryCarveout = CUshared_carveout.MaxShared;

                meanTail = ctx.LoadKernelPTX(resourceStream, "FluffyTail");
                meanTail.BlockDimensions = 1024;
                meanTail.GridDimensions  = 4096;
                meanTail.PreferredSharedMemoryCarveout = CUshared_carveout.MaxL1;

                meanRecover = ctx.LoadKernelPTX(resourceStream, "FluffyRecovery");
                meanRecover.BlockDimensions = 256;
                meanRecover.GridDimensions  = 2048;
                meanRecover.PreferredSharedMemoryCarveout = CUshared_carveout.MaxL1;
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Unable to create kernels: " + ex.Message);
                Task.Delay(500).Wait();
                Comms.Close();
                return;
            }

            try
            {
                d_buffer    = new CudaDeviceVariable <ulong>(BUFFER_SIZE_U32);
                d_bufferMid = new CudaDeviceVariable <ulong>(d_buffer.DevicePointer + (BUFFER_SIZE_B * 8));
                d_bufferB   = new CudaDeviceVariable <ulong>(d_buffer.DevicePointer + (BUFFER_SIZE_A * 8));

                d_indexesA = new CudaDeviceVariable <uint>(INDEX_SIZE * 2);
                d_indexesB = new CudaDeviceVariable <uint>(INDEX_SIZE * 2);

                Array.Clear(h_indexesA, 0, h_indexesA.Length);
                Array.Clear(h_indexesB, 0, h_indexesA.Length);

                d_indexesA = h_indexesA;
                d_indexesB = h_indexesB;

                streamPrimary   = new CudaStream(CUStreamFlags.NonBlocking);
                streamSecondary = new CudaStream(CUStreamFlags.NonBlocking);
            }
            catch (Exception ex)
            {
                Task.Delay(200).Wait();
                Logger.Log(LogLevel.Error, $"Out of video memory! Only {ctx.GetFreeDeviceMemorySize()} free");
                Task.Delay(500).Wait();
                Comms.Close();
                return;
            }

            try
            {
                AllocateHostMemory(true, ref h_a, ref hAligned_a, 1024 * 1024 * 32);
            }
            catch (Exception ex)
            {
                Logger.Log(LogLevel.Error, "Unable to create pinned memory.");
                Task.Delay(500).Wait();
                Comms.Close();
                return;
            }

            int loopCnt = 0;

            while (!Comms.IsTerminated)
            {
                try
                {
                    if (!TEST && (Comms.nextJob.pre_pow == null || Comms.nextJob.pre_pow == "" || Comms.nextJob.pre_pow == TestPrePow))
                    {
                        Logger.Log(LogLevel.Info, string.Format("Waiting for job...."));
                        Task.Delay(1000).Wait();
                        continue;
                    }

                    if (!TEST && ((currentJob.pre_pow != Comms.nextJob.pre_pow) || (currentJob.origin != Comms.nextJob.origin)))
                    {
                        currentJob           = Comms.nextJob;
                        currentJob.timestamp = DateTime.Now;
                    }

                    if (!TEST && (currentJob.timestamp.AddMinutes(30) < DateTime.Now) && Comms.lastIncoming.AddMinutes(30) < DateTime.Now)
                    {
                        Logger.Log(LogLevel.Info, string.Format("Job too old..."));
                        Task.Delay(1000).Wait();
                        continue;
                    }

                    // test runs only once
                    if (TEST && loopCnt++ > 100)
                    {
                        Comms.IsTerminated = true;
                    }

                    Solution s;
                    while (graphSolutions.TryDequeue(out s))
                    {
                        meanRecover.SetConstantVariable <ulong>("recovery", s.GetUlongEdges());
                        d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                        meanRecover.RunAsync(streamPrimary.Stream, s.job.k0, s.job.k1, s.job.k2, s.job.k3, d_indexesB.DevicePointer);
                        streamPrimary.Synchronize();
                        s.nonces = new uint[40];
                        d_indexesB.CopyToHost(s.nonces, 0, 0, 40 * 4);
                        s.nonces = s.nonces.OrderBy(n => n).ToArray();
                        lock (Comms.graphSolutionsOut)
                        {
                            Comms.graphSolutionsOut.Enqueue(s);
                        }
                        Comms.SetEvent();
                    }
                    uint[] count;
                    do
                    {
                        if (!TEST && ((currentJob.pre_pow != Comms.nextJob.pre_pow) || (currentJob.origin != Comms.nextJob.origin)))
                        {
                            currentJob           = Comms.nextJob;
                            currentJob.timestamp = DateTime.Now;
                        }
                        currentJob = currentJob.Next();

                        Logger.Log(LogLevel.Debug, string.Format("GPU NV{4}:Trimming #{4}: {0} {1} {2} {3}", currentJob.k0, currentJob.k1, currentJob.k2, currentJob.k3, currentJob.jobID, deviceID));

                        timer.Restart();

                        d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                        d_indexesB.MemsetAsync(0, streamPrimary.Stream);

                        meanSeedA.RunAsync(streamPrimary.Stream, currentJob.k0, currentJob.k1, currentJob.k2, currentJob.k3, d_bufferMid.DevicePointer, d_indexesB.DevicePointer);
                        meanSeedB_4.RunAsync(streamPrimary.Stream, d_bufferMid.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, 0);
                        meanSeedB_4.RunAsync(streamPrimary.Stream, d_bufferMid.DevicePointer, d_buffer.DevicePointer + ((BUFFER_SIZE_A * 8) / 4) * 1, d_indexesB.DevicePointer, d_indexesA.DevicePointer, 16);
                        meanSeedB_4.RunAsync(streamPrimary.Stream, d_bufferMid.DevicePointer, d_buffer.DevicePointer + ((BUFFER_SIZE_A * 8) / 4) * 2, d_indexesB.DevicePointer, d_indexesA.DevicePointer, 32);
                        meanSeedB_4.RunAsync(streamPrimary.Stream, d_bufferMid.DevicePointer, d_buffer.DevicePointer + ((BUFFER_SIZE_A * 8) / 4) * 3, d_indexesB.DevicePointer, d_indexesA.DevicePointer, 48);

                        d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                        meanRound_2.RunAsync(streamPrimary.Stream, d_buffer.DevicePointer + ((BUFFER_SIZE_A * 8) / 4) * 2, d_bufferB.DevicePointer, d_indexesA.DevicePointer + (2048 * 4), d_indexesB.DevicePointer + (4096 * 4), DUCK_EDGES_A, DUCK_EDGES_B / 2);
                        meanRound_2.RunAsync(streamPrimary.Stream, d_buffer.DevicePointer, d_bufferB.DevicePointer - (BUFFER_SIZE_B * 8), d_indexesA.DevicePointer, d_indexesB.DevicePointer, DUCK_EDGES_A, DUCK_EDGES_B / 2);
                        d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                        meanRoundJoin.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer - (BUFFER_SIZE_B * 8), d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_B / 2, DUCK_EDGES_B / 2);

                        //d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                        //meanRound.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_B, DUCK_EDGES_B / 2);
                        d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                        meanRound.RunAsync(streamPrimary.Stream, d_buffer.DevicePointer, d_bufferB.DevicePointer, d_indexesA.DevicePointer, d_indexesB.DevicePointer, DUCK_EDGES_B / 2, DUCK_EDGES_B / 2);
                        d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                        meanRound.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_B / 2, DUCK_EDGES_B / 2);
                        d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                        meanRound.RunAsync(streamPrimary.Stream, d_buffer.DevicePointer, d_bufferB.DevicePointer, d_indexesA.DevicePointer, d_indexesB.DevicePointer, DUCK_EDGES_B / 2, DUCK_EDGES_B / 4);

                        for (int i = 0; i < trimRounds; i++)
                        {
                            d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                            meanRound.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer, DUCK_EDGES_B / 4, DUCK_EDGES_B / 4);
                            d_indexesB.MemsetAsync(0, streamPrimary.Stream);
                            meanRound.RunAsync(streamPrimary.Stream, d_buffer.DevicePointer, d_bufferB.DevicePointer, d_indexesA.DevicePointer, d_indexesB.DevicePointer, DUCK_EDGES_B / 4, DUCK_EDGES_B / 4);
                        }

                        d_indexesA.MemsetAsync(0, streamPrimary.Stream);
                        meanTail.RunAsync(streamPrimary.Stream, d_bufferB.DevicePointer, d_buffer.DevicePointer, d_indexesB.DevicePointer, d_indexesA.DevicePointer);

                        ctx.Synchronize();
                        streamPrimary.Synchronize();

                        count = new uint[2];
                        d_indexesA.CopyToHost(count, 0, 0, 8);

                        if (count[0] > 4194304)
                        {
                            // trouble
                            count[0] = 4194304;
                            // log
                        }

                        hAligned_a.AsyncCopyFromDevice(d_buffer.DevicePointer, 0, 0, count[0] * 8, streamPrimary.Stream);
                        streamPrimary.Synchronize();
                        System.Runtime.InteropServices.Marshal.Copy(hAligned_a.PinnedHostPointer, h_a, 0, ((int)count[0] * 8) / sizeof(int));

                        timer.Stop();
                        currentJob.solvedAt = DateTime.Now;
                        currentJob.trimTime = timer.ElapsedMilliseconds;

                        //Console.WriteLine("Trimmed in {0}ms to {1} edges", timer.ElapsedMilliseconds, count[0]);
                        Logger.Log(LogLevel.Info, string.Format("GPU NV{2}:     Trimmed in {0}ms to {1} edges, h {3}", timer.ElapsedMilliseconds, count[0], deviceID, currentJob.height));
                    }while((currentJob.height != Comms.nextJob.height) && (!Comms.IsTerminated) && (!TEST));

                    if (TEST)
                    {
                        //Console.WriteLine("Trimmed in {0}ms to {1} edges", timer.ElapsedMilliseconds, count[0]);

                        CGraph cg = FinderBag.GetFinder();
                        if (cg == null)
                        {
                            continue;
                        }

                        cg.SetEdges(h_a, (int)count[0]);
                        cg.SetHeader(currentJob);

                        //currentJob = currentJob.Next();

                        Task.Factory.StartNew(() =>
                        {
                            Stopwatch sw = new Stopwatch();
                            sw.Start();

                            if (count[0] < 200000)
                            {
                                try
                                {
                                    if (findersInFlight++ < 3)
                                    {
                                        Stopwatch cycleTime = new Stopwatch();
                                        cycleTime.Start();
                                        cg.FindSolutions(graphSolutions);
                                        cycleTime.Stop();
                                        AdjustTrims(cycleTime.ElapsedMilliseconds);
                                        if (graphSolutions.Count > 0)
                                        {
                                            solutions++;
                                        }
                                    }
                                    else
                                    {
                                        Logger.Log(LogLevel.Warning, "CPU overloaded!");
                                    }
                                }
                                catch (Exception ex)
                                {
                                    Logger.Log(LogLevel.Error, "Cycle finder error" + ex.Message);
                                }
                                finally
                                {
                                    findersInFlight--;
                                    FinderBag.ReturnFinder(cg);
                                }
                            }

                            sw.Stop();

                            if (++trims % 50 == 0)
                            {
                                Console.ForegroundColor = ConsoleColor.Green;
                                Console.WriteLine("SOLS: {0}/{1} - RATE: {2:F1}", solutions, trims, (float)trims / solutions);
                                Console.ResetColor();
                            }
                            //Console.WriteLine("Finder completed in {0}ms on {1} edges with {2} solution(s)", sw.ElapsedMilliseconds, count[0], graphSolutions.Count);
                            //Console.WriteLine("Duped edges: {0}", cg.dupes);
                            Logger.Log(LogLevel.Info, string.Format("Finder completed in {0}ms on {1} edges with {2} solution(s) and {3} dupes", sw.ElapsedMilliseconds, count[0], graphSolutions.Count, cg.dupes));
                        });

                        //h_indexesA = d_indexesA;
                        //h_indexesB = d_indexesB;

                        //var sumA = h_indexesA.Sum(e => e);
                        //var sumB = h_indexesB.Sum(e => e);

                        ;
                    }
                    else
                    {
                        CGraph cg = FinderBag.GetFinder();
                        cg.SetEdges(h_a, (int)count[0]);
                        cg.SetHeader(currentJob);

                        Task.Factory.StartNew(() =>
                        {
                            if (count[0] < 200000)
                            {
                                try
                                {
                                    if (findersInFlight++ < 3)
                                    {
                                        Stopwatch cycleTime = new Stopwatch();
                                        cycleTime.Start();
                                        cg.FindSolutions(graphSolutions);
                                        cycleTime.Stop();
                                        AdjustTrims(cycleTime.ElapsedMilliseconds);
                                        if (graphSolutions.Count > 0)
                                        {
                                            solutions++;
                                        }
                                    }
                                    else
                                    {
                                        Logger.Log(LogLevel.Warning, "CPU overloaded!");
                                    }
                                }
                                catch (Exception ex)
                                {
                                    Logger.Log(LogLevel.Error, "Cycle finder crashed: " + ex.Message);
                                }
                                finally
                                {
                                    findersInFlight--;
                                    FinderBag.ReturnFinder(cg);
                                }
                            }
                        });
                    }
                }
                catch (Exception ex)
                {
                    Logger.Log(LogLevel.Error, "Critical error in main cuda loop " + ex.Message);
                    Task.Delay(5000).Wait();
                }
            }

            // clean up
            try
            {
                Task.Delay(500).Wait();

                Comms.Close();

                d_buffer.Dispose();
                d_indexesA.Dispose();
                d_indexesB.Dispose();

                streamPrimary.Dispose();
                streamSecondary.Dispose();

                hAligned_a.Dispose();

                if (ctx != null)
                {
                    ctx.Dispose();
                }
            }
            catch { }
        }
Exemplo n.º 15
0
        static void Main(string[] args)
        {
            int SIGNAL_SIZE = 50;
            int FILTER_KERNEL_SIZE = 11;

            Console.WriteLine("[simpleCUFFT] is starting...");

            var assembly = Assembly.GetExecutingAssembly();
            var resourceName = "simpleCUFFT.simpleCUFFTKernel.ptx";

            CudaContext ctx = new CudaContext(0);
            CudaKernel ComplexPointwiseMulAndScale;
            string[] liste = assembly.GetManifestResourceNames();
            using (Stream stream = assembly.GetManifestResourceStream(resourceName))
            {
                ComplexPointwiseMulAndScale = ctx.LoadKernelPTX(stream, "ComplexPointwiseMulAndScale");
            }

            // Allocate host memory for the signal
            cuFloatComplex[] h_signal = new cuFloatComplex[SIGNAL_SIZE]; //we use cuFloatComplex for complex multiplaction in reference host code...

            Random rand = new Random(0);
            // Initialize the memory for the signal
            for (int i = 0; i < SIGNAL_SIZE; ++i)
            {
                h_signal[i].real = (float)rand.NextDouble();
                h_signal[i].imag = 0;
            }

            // Allocate host memory for the filter
            cuFloatComplex[] h_filter_kernel = new cuFloatComplex[FILTER_KERNEL_SIZE];

            // Initialize the memory for the filter
            for (int i = 0; i < FILTER_KERNEL_SIZE; ++i)
            {
                h_filter_kernel[i].real = (float)rand.NextDouble();
                h_filter_kernel[i].imag = 0;
            }

            // Pad signal and filter kernel
            cuFloatComplex[] h_padded_signal = null;
            cuFloatComplex[] h_padded_filter_kernel = null;
            int new_size = PadData(h_signal, ref h_padded_signal, SIGNAL_SIZE,
                                   h_filter_kernel, ref h_padded_filter_kernel, FILTER_KERNEL_SIZE);
            int mem_size = (int)cuFloatComplex.SizeOf * new_size;

            // Allocate device memory for signal
            CudaDeviceVariable<cuFloatComplex> d_signal = new CudaDeviceVariable<cuFloatComplex>(new_size);
            // Copy host memory to device
            d_signal.CopyToDevice(h_padded_signal);

            // Allocate device memory for filter kernel
            CudaDeviceVariable<cuFloatComplex> d_filter_kernel = new CudaDeviceVariable<cuFloatComplex>(new_size);

            // Copy host memory to device
            d_filter_kernel.CopyToDevice(h_padded_filter_kernel);

            // CUFFT plan simple API
            CudaFFTPlan1D plan = new CudaFFTPlan1D(new_size, cufftType.C2C, 1);

            // Transform signal and kernel
            Console.WriteLine("Transforming signal cufftExecC2C");
            plan.Exec(d_signal.DevicePointer, TransformDirection.Forward);
            plan.Exec(d_filter_kernel.DevicePointer, TransformDirection.Forward);

            // Multiply the coefficients together and normalize the result
            Console.WriteLine("Launching ComplexPointwiseMulAndScale<<< >>>");
            ComplexPointwiseMulAndScale.BlockDimensions = 256;
            ComplexPointwiseMulAndScale.GridDimensions = 32;
            ComplexPointwiseMulAndScale.Run(d_signal.DevicePointer, d_filter_kernel.DevicePointer, new_size, 1.0f / new_size);

            // Transform signal back
            Console.WriteLine("Transforming signal back cufftExecC2C");
            plan.Exec(d_signal.DevicePointer, TransformDirection.Inverse);

            // Copy device memory to host
            cuFloatComplex[] h_convolved_signal = d_signal;

            // Allocate host memory for the convolution result
            cuFloatComplex[] h_convolved_signal_ref = new cuFloatComplex[SIGNAL_SIZE];

            // Convolve on the host
            Convolve(h_signal, SIGNAL_SIZE,
                     h_filter_kernel, FILTER_KERNEL_SIZE,
                     h_convolved_signal_ref);

            // check result
            bool bTestResult = sdkCompareL2fe(h_convolved_signal_ref, h_convolved_signal, 1e-5f);

            //Destroy CUFFT context
            plan.Dispose();

            // cleanup memory
            d_filter_kernel.Dispose();
            d_signal.Dispose();
            ctx.Dispose();

            if (bTestResult)
            {
                Console.WriteLine("Test Passed");
            }
            else
            {
                Console.WriteLine("Test Failed");
            }
        }
        public RtRaster <double> RunGpuInterpolation(YieldReportData dataPoints, IGeometry dataBoundary)
        {
            try
            {
                int cellSize = 1;
                var bounds   = new RTBounds(dataBoundary).ToMeters();
                var xMax     = bounds.MaxX;
                var xMin     = bounds.MinX;
                var yMax     = bounds.MaxY;
                var yMin     = bounds.MinY;
                var xDist    = (int)(xMax - xMin + 1);
                var yDist    = (int)(yMax - yMin + 1);
                //var cost = (xDist * yDist * dataPoints.Count) / (Environment.ProcessorCount * cellSize * cellSize);
                var nCols = xDist / cellSize;
                var nRows = yDist / cellSize;

                CollectionStats yld = dataPoints.YieldData.Yield;
                //create host side arrays for input data and boundary and output data
                double[] h_datax = yld.DataPoints.Select(pt => RtPoint <double> .LatLonToMeters(pt)).Select(ptz => ptz.X).ToArray();
                double[] h_datay = yld.DataPoints.Select(pt => RtPoint <double> .LatLonToMeters(pt)).Select(ptz => ptz.Y).ToArray();
                double[] h_dataz = yld.DataPoints.Select(pt => RtPoint <double> .LatLonToMeters(pt)).Select(ptz => ptz.Z).ToArray();

                var dataSize = sizeof(double) * h_datax.Length;
                Console.WriteLine("Performing interpolation on {0} data points of {1} bytes", h_datax.Length, dataSize);
                var      cols      = Enumerable.Range(0, nCols - 1).ToArray();
                var      coords    = Enumerable.Range(0, nRows).SelectMany(row => cols.Select(col => Tuple.Create(row, col))).ToArray();
                double[] h_outputx = coords.Select(coord => xMin + (coord.Item2 * cellSize)).ToArray();
                double[] h_outputy = coords.Select(coord => yMin + (coord.Item1 * cellSize)).ToArray();
                double[] h_outputz = coords.Select(coord => 0.0).ToArray();

                var outputSize = sizeof(double) * h_outputx.Length;
                Console.WriteLine("Output Raster has {0} raster points of {1} bytes", h_outputx.Length, outputSize);
                double2[] h_boundCoords = dataBoundary.Coordinates.Select(coord => new double2(coord.X, coord.Y)).ToArray();
                using (CudaDeviceVariable <double> d_datax = h_datax)
                    using (CudaDeviceVariable <double> d_datay = h_datay)
                        using (CudaDeviceVariable <double> d_dataz = h_dataz)
                            using (CudaDeviceVariable <double> d_outputx = h_outputx)
                                using (CudaDeviceVariable <double> d_outputy = h_outputy)
                                    using (CudaDeviceVariable <double> d_outputz = h_outputz)
                                    {
                                        const int ThreadsPerBlock = 512;
                                        InterpolateKernel.BlockDimensions = ThreadsPerBlock;
                                        InterpolateKernel.GridDimensions  = (h_outputx.Length + ThreadsPerBlock - 1) / ThreadsPerBlock;
                                        Console.WriteLine("Invoke Kernel with Grid Dimensions = {0}", InterpolateKernel.GridDimensions);

                                        Stopwatch timer = new Stopwatch();
                                        timer.Start();
                                        InterpolateKernel.Run(d_datax.DevicePointer, d_datay.DevicePointer, d_dataz.DevicePointer,
                                                              d_outputx.DevicePointer, d_outputy.DevicePointer, d_outputz.DevicePointer,
                                                              h_outputx.Length, h_datax.Length);
                                        timer.Stop();
                                        var elapsed = timer.ElapsedTicks;
                                        Console.WriteLine("Gpu Interpolation took {0} ms", elapsed / (Stopwatch.Frequency / 1000));
                                        h_outputz = d_outputz;
                                    }

                if (h_outputz.All(pt => pt != 0.0))
                {
                    Console.WriteLine("Kernel succeeded");
                }
                else
                {
                    Console.WriteLine("Kernel failed");
                }

                var raster      = new RtRaster <double>(nCols, nRows, xMin, yMin, cellSize * 2);
                var noDataValue = 0.0f;
                var rasterBand  = RtRasterBand <double> .CreateRasterBand(typeof(double), nCols, nRows, noDataValue, h_outputz);

                raster.SetRasterBand(0, rasterBand);

                return(raster);
            }


            catch (Exception ex)
            {
                ctx.Dispose();

                Console.WriteLine(ex.Message + "\nStackTrace: " + ex.StackTrace);
                //+
                //    ex.InnerException == null ? "" :
                //    String.Format("\n\t{0}\n\tStackTrace: {1}", ex.InnerException.Message,
                //    ex.InnerException.StackTrace)

                return(null);
            }
        }
Exemplo n.º 17
0
        static void Main(string[] args)
        {
            const int nx = 2048;
            const int ny = 2048;

            // shifts applied to x and y data
            const int x_shift = 5;
            const int y_shift = 7;

            ShrQATest.shrQAStart(args);

            if ((nx % TILE_DIM != 0) || (ny % TILE_DIM != 0))
            {
                Console.Write("nx and ny must be multiples of TILE_DIM\n");
                ShrQATest.shrQAFinishExit(args, ShrQATest.eQAstatus.QA_WAIVED);
            }

            // execution configuration parameters
            dim3 grid    = new dim3(nx / TILE_DIM, ny / TILE_DIM, 1);
            dim3 threads = new dim3(TILE_DIM, TILE_DIM, 1);

            // This will pick the best possible CUDA capable device
            int devID = findCudaDevice(args);


            //Load Kernel image from resources
            string resName;

            if (IntPtr.Size == 8)
            {
                resName = "simplePitchLinearTexture_x64.ptx";
            }
            else
            {
                resName = "simplePitchLinearTexture.ptx";
            }

            string resNamespace = "simplePitchLinearTexture";
            string resource     = resNamespace + "." + resName;
            Stream stream       = Assembly.GetExecutingAssembly().GetManifestResourceStream(resource);

            if (stream == null)
            {
                throw new ArgumentException("Kernel not found in resources.");
            }
            byte[] kernels = new byte[stream.Length];

            int bytesToRead = (int)stream.Length;

            while (bytesToRead > 0)
            {
                bytesToRead -= stream.Read(kernels, (int)stream.Position, bytesToRead);
            }

            CudaKernel PLKernel    = ctx.LoadKernelPTX(kernels, "shiftPitchLinear");
            CudaKernel ArrayKernel = ctx.LoadKernelPTX(kernels, "shiftArray");

            CudaStopWatch stopwatch = new CudaStopWatch();

            // ----------------------------------
            // Host allocation and initialization
            // ----------------------------------

            float[] h_idata = new float[nx * ny];
            float[] h_odata = new float[nx * ny];
            float[] gold    = new float[nx * ny];

            for (int i = 0; i < nx * ny; ++i)
            {
                h_idata[i] = (float)i;
            }

            // ------------------------
            // Device memory allocation
            // ------------------------

            // Pitch linear input data
            CudaPitchedDeviceVariable <float> d_idataPL = new CudaPitchedDeviceVariable <float>(nx, ny);

            // Array input data
            CudaArray2D d_idataArray = new CudaArray2D(CUArrayFormat.Float, nx, ny, CudaArray2DNumChannels.One);

            // Pitch linear output data
            CudaPitchedDeviceVariable <float> d_odata = new CudaPitchedDeviceVariable <float>(nx, ny);

            // ------------------------
            // copy host data to device
            // ------------------------

            // Pitch linear
            d_idataPL.CopyToDevice(h_idata);

            // Array
            d_idataArray.CopyFromHostToThis <float>(h_idata);

            // ----------------------
            // Bind texture to memory
            // ----------------------

            // Pitch linear
            CudaTextureLinearPitched2D <float> texRefPL = new CudaTextureLinearPitched2D <float>(PLKernel, "texRefPL", CUAddressMode.Wrap, CUFilterMode.Point, CUTexRefSetFlags.NormalizedCoordinates, CUArrayFormat.Float, d_idataPL);
            CudaTextureArray2D texRefArray = new CudaTextureArray2D(ArrayKernel, "texRefArray", CUAddressMode.Wrap, CUFilterMode.Point, CUTexRefSetFlags.NormalizedCoordinates, d_idataArray);

            // ---------------------
            // reference calculation
            // ---------------------

            for (int j = 0; j < ny; j++)
            {
                int jshift = (j + y_shift) % ny;
                for (int i = 0; i < nx; i++)
                {
                    int ishift = (i + x_shift) % nx;
                    gold[j * nx + i] = h_idata[jshift * nx + ishift];
                }
            }

            // ----------------
            // shiftPitchLinear
            // ----------------

            ctx.ClearMemory(d_odata.DevicePointer, 0, d_odata.TotalSizeInBytes);
            PLKernel.BlockDimensions = threads;
            PLKernel.GridDimensions  = grid;
            stopwatch.Start();
            for (int i = 0; i < NUM_REPS; i++)
            {
                PLKernel.Run(d_odata.DevicePointer, (int)(d_odata.Pitch / sizeof(float)), nx, ny, x_shift, y_shift);
            }
            stopwatch.Stop();
            stopwatch.StopEvent.Synchronize();
            float timePL = stopwatch.GetElapsedTime();

            // check results
            d_odata.CopyToHost(h_odata);

            bool res = cutComparef(gold, h_odata);

            bool success = true;

            if (res == false)
            {
                Console.Write("*** shiftPitchLinear failed ***\n");
                success = false;
            }

            // ----------
            // shiftArray
            // ----------

            ctx.ClearMemory(d_odata.DevicePointer, 0, d_odata.TotalSizeInBytes);
            ArrayKernel.BlockDimensions = threads;
            ArrayKernel.GridDimensions  = grid;
            stopwatch.Start();
            for (int i = 0; i < NUM_REPS; i++)
            {
                ArrayKernel.Run(d_odata.DevicePointer, (int)(d_odata.Pitch / sizeof(float)), nx, ny, x_shift, y_shift);
            }

            stopwatch.Stop();
            stopwatch.StopEvent.Synchronize();
            float timeArray = stopwatch.GetElapsedTime();

            // check results
            d_odata.CopyToHost(h_odata);

            res = cutComparef(gold, h_odata);

            if (res == false)
            {
                Console.Write("*** shiftArray failed ***\n");
                success = false;
            }

            float bandwidthPL    = 2.0f * 1000.0f * nx * ny * sizeof(float) / (1e+9f) / (timePL / NUM_REPS);
            float bandwidthArray = 2.0f * 1000.0f * nx * ny * sizeof(float) / (1e+9f) / (timeArray / NUM_REPS);

            Console.Write("\nBandwidth (GB/s) for pitch linear: {0}; for array: {1}\n",
                          bandwidthPL, bandwidthArray);

            float fetchRatePL    = nx * ny / 1e+6f / (timePL / (1000.0f * NUM_REPS));
            float fetchRateArray = nx * ny / 1e+6f / (timeArray / (1000.0f * NUM_REPS));

            Console.Write("\nTexture fetch rate (Mpix/s) for pitch linear: {0}; for array: {1}\n\n",
                          fetchRatePL, fetchRateArray);


            // cleanup
            texRefPL.Dispose();
            texRefArray.Dispose();
            d_idataPL.Dispose();
            d_idataArray.Dispose();
            d_odata.Dispose();
            stopwatch.Dispose();
            ctx.Dispose();

            ShrQATest.shrQAFinishExit(args, (success == true) ? ShrQATest.eQAstatus.QA_PASSED : ShrQATest.eQAstatus.QA_FAILED);
        }
Exemplo n.º 18
0
 void OnDestroy()
 {
     ctx.Dispose();
 }
        private void myWindow_Closing(object sender, System.ComponentModel.CancelEventArgs e)
        {
            //Stop render loop before closing
            if (frameTimer != null)
            {
                frameTimer.Tick -= new EventHandler(frameTimer_Tick);
                frameTimer.Stop();
            }

            //Cleanup
            if (graphicsres != null)
            {
                graphicsres.Dispose();
            }
            if (g_mparticles != null)
            {
                g_mparticles.Dispose();
            }
            if (stopwatch != null)
            {
                stopwatch.Dispose();
            }

            if (texref != null)
            {
                texref.Dispose();
            }
            if (g_dvfield != null)
            {
                g_dvfield.Dispose();
            }
            if (g_vxfield != null)
            {
                g_vxfield.Dispose();
            }
            if (g_vyfield != null)
            {
                g_vyfield.Dispose();
            }

            if (g_planc2r != null)
            {
                g_planc2r.Dispose();
            }
            if (g_planr2c != null)
            {
                g_planr2c.Dispose();
            }

            if (g_pVB != null)
            {
                g_pVB.Dispose();
            }
            if (g_pTexture != null)
            {
                g_pTexture.Dispose();
            }

            if (device != null)
            {
                device.Dispose();
            }
            if (d3d != null)
            {
                d3d.Dispose();
            }

            if (ctx != null)
            {
                ctx.Dispose();
            }
        }
Exemplo n.º 20
0
 public override void Dispose()
 {
     cuBlas.Dispose();
     cudaContext.Dispose();
 }
Exemplo n.º 21
0
        static void Main(string[] args)
        {
            string filename = "vectorAdd_kernel.cu"; //we assume the file is in the same folder...
            string fileToCompile = File.ReadAllText(filename);

            CudaRuntimeCompiler rtc = new CudaRuntimeCompiler(fileToCompile, "vectorAdd_kernel");

            rtc.Compile(args);

            string log = rtc.GetLogAsString();

            Console.WriteLine(log);

            byte[] ptx = rtc.GetPTX();

            rtc.Dispose();

            CudaContext ctx = new CudaContext(0);

            CudaKernel vectorAdd = ctx.LoadKernelPTX(ptx, "vectorAdd");

            // Print the vector length to be used, and compute its size
            int numElements = 50000;
            SizeT size = numElements * sizeof(float);
            Console.WriteLine("[Vector addition of {0} elements]", numElements);

            // Allocate the host input vector A
            float[] h_A = new float[numElements];
            // Allocate the host input vector B
            float[] h_B = new float[numElements];
            // Allocate the host output vector C
            float[] h_C = new float[numElements];

            Random rand = new Random(0);

            // Initialize the host input vectors
            for (int i = 0; i < numElements; ++i)
            {
                h_A[i] = (float)rand.NextDouble();
                h_B[i] = (float)rand.NextDouble();
            }

            Console.WriteLine("Allocate and copy input data from the host memory to the CUDA device\n");
            // Allocate the device input vector A and copy to device
            CudaDeviceVariable<float> d_A = h_A;

            // Allocate the device input vector B and copy to device
            CudaDeviceVariable<float> d_B = h_B;

            // Allocate the device output vector C
            CudaDeviceVariable<float> d_C = new CudaDeviceVariable<float>(numElements);

            // Launch the Vector Add CUDA Kernel
            int threadsPerBlock = 256;
            int blocksPerGrid = (numElements + threadsPerBlock - 1) / threadsPerBlock;
            Console.WriteLine("CUDA kernel launch with {0} blocks of {1} threads\n", blocksPerGrid, threadsPerBlock);
            vectorAdd.BlockDimensions = new dim3(threadsPerBlock,1, 1);
            vectorAdd.GridDimensions = new dim3(blocksPerGrid, 1, 1);

            vectorAdd.Run(d_A.DevicePointer, d_B.DevicePointer, d_C.DevicePointer, numElements);

            // Copy the device result vector in device memory to the host result vector
            // in host memory.
            Console.WriteLine("Copy output data from the CUDA device to the host memory\n");
            d_C.CopyToHost(h_C);

            // Verify that the result vector is correct
            for (int i = 0; i < numElements; ++i)
            {
                if (Math.Abs(h_A[i] + h_B[i] - h_C[i]) > 1e-5)
                {
                    Console.WriteLine("Result verification failed at element {0}!\n", i);
                    return;
                }
            }

            Console.WriteLine("Test PASSED\n");

            // Free device global memory
            d_A.Dispose();
            d_B.Dispose();
            d_C.Dispose();

            ctx.Dispose();
            Console.WriteLine("Done\n");
        }
Exemplo n.º 22
0
        static void Main(string[] args)
        {
            string filename      = "vectorAdd_kernel.cu"; //we assume the file is in the same folder...
            string fileToCompile = File.ReadAllText(filename);


            CudaRuntimeCompiler rtc = new CudaRuntimeCompiler(fileToCompile, "vectorAdd_kernel");

            rtc.Compile(args);

            string log = rtc.GetLogAsString();

            Console.WriteLine(log);

            byte[] ptx = rtc.GetPTX();

            rtc.Dispose();

            CudaContext ctx = new CudaContext(0);

            CudaKernel vectorAdd = ctx.LoadKernelPTX(ptx, "vectorAdd");


            // Print the vector length to be used, and compute its size
            int   numElements = 50000;
            SizeT size        = numElements * sizeof(float);

            Console.WriteLine("[Vector addition of {0} elements]", numElements);

            // Allocate the host input vector A
            float[] h_A = new float[numElements];
            // Allocate the host input vector B
            float[] h_B = new float[numElements];
            // Allocate the host output vector C
            float[] h_C = new float[numElements];

            Random rand = new Random(0);

            // Initialize the host input vectors
            for (int i = 0; i < numElements; ++i)
            {
                h_A[i] = (float)rand.NextDouble();
                h_B[i] = (float)rand.NextDouble();
            }

            Console.WriteLine("Allocate and copy input data from the host memory to the CUDA device\n");
            // Allocate the device input vector A and copy to device
            CudaDeviceVariable <float> d_A = h_A;

            // Allocate the device input vector B and copy to device
            CudaDeviceVariable <float> d_B = h_B;

            // Allocate the device output vector C
            CudaDeviceVariable <float> d_C = new CudaDeviceVariable <float>(numElements);

            // Launch the Vector Add CUDA Kernel
            int threadsPerBlock = 256;
            int blocksPerGrid   = (numElements + threadsPerBlock - 1) / threadsPerBlock;

            Console.WriteLine("CUDA kernel launch with {0} blocks of {1} threads\n", blocksPerGrid, threadsPerBlock);
            vectorAdd.BlockDimensions = new dim3(threadsPerBlock, 1, 1);
            vectorAdd.GridDimensions  = new dim3(blocksPerGrid, 1, 1);

            vectorAdd.Run(d_A.DevicePointer, d_B.DevicePointer, d_C.DevicePointer, numElements);

            // Copy the device result vector in device memory to the host result vector
            // in host memory.
            Console.WriteLine("Copy output data from the CUDA device to the host memory\n");
            d_C.CopyToHost(h_C);


            // Verify that the result vector is correct
            for (int i = 0; i < numElements; ++i)
            {
                if (Math.Abs(h_A[i] + h_B[i] - h_C[i]) > 1e-5)
                {
                    Console.WriteLine("Result verification failed at element {0}!\n", i);
                    return;
                }
            }

            Console.WriteLine("Test PASSED\n");

            // Free device global memory
            d_A.Dispose();
            d_B.Dispose();
            d_C.Dispose();

            ctx.Dispose();
            Console.WriteLine("Done\n");
        }
Exemplo n.º 23
0
        private void Form1_FormClosing(object sender, FormClosingEventArgs e)
        {
            isRunning = false;

            //Cleanup
            if (graphicsres != null)
            {
                graphicsres.Dispose();
            }
            if (g_mparticles != null)
            {
                g_mparticles.Dispose();
            }
            if (stopwatch != null)
            {
                stopwatch.Dispose();
            }

            if (texref != null)
            {
                texref.Dispose();
            }
            if (g_dvfield != null)
            {
                g_dvfield.Dispose();
            }
            if (g_vxfield != null)
            {
                g_vxfield.Dispose();
            }
            if (g_vyfield != null)
            {
                g_vyfield.Dispose();
            }

            if (g_planc2r != null)
            {
                g_planc2r.Dispose();
            }
            if (g_planr2c != null)
            {
                g_planr2c.Dispose();
            }

            if (g_pVB != null)
            {
                g_pVB.Dispose();
            }
            if (g_pTexture != null)
            {
                g_pTexture.Dispose();
            }

            if (device != null)
            {
                device.Dispose();
            }
            if (d3d != null)
            {
                d3d.Dispose();
            }

            if (ctx != null)
            {
                ctx.Dispose();
            }
        }
        public void cuFFTreconstruct()
        {
            CudaContext ctx = new CudaContext(0);

            ManagedCuda.BasicTypes.CUmodule cumodule = ctx.LoadModule("kernel.ptx");
            CudaKernel cuKernel = new CudaKernel("cu_ArrayInversion", cumodule, ctx);

            float2[] fData  = new float2[Resolution * Resolution];
            float2[] result = new float2[Resolution * Resolution];
            FFTData2D = new float[Resolution, Resolution, 2];
            CudaDeviceVariable <float2> devData      = new CudaDeviceVariable <float2>(Resolution * Resolution);
            CudaDeviceVariable <float2> copy_devData = new CudaDeviceVariable <float2>(Resolution * Resolution);

            int    i, j;
            Random rnd  = new Random();
            double avrg = 0.0;

            for (i = 0; i < Resolution; i++)
            {
                for (j = 0; j < Resolution; j++)
                {
                    fData[i * Resolution + j].x = i + j * 2;
                    avrg += fData[i * Resolution + j].x;
                    fData[i * Resolution + j].y = 0.0f;
                }
            }

            avrg = avrg / (double)(Resolution * Resolution);

            for (i = 0; i < Resolution; i++)
            {
                for (j = 0; j < Resolution; j++)
                {
                    fData[(i * Resolution + j)].x = fData[(i * Resolution + j)].x - (float)avrg;
                }
            }

            devData.CopyToDevice(fData);

            CudaFFTPlan1D plan1D = new CudaFFTPlan1D(Resolution, cufftType.C2C, Resolution);

            plan1D.Exec(devData.DevicePointer, TransformDirection.Forward);

            cuKernel.GridDimensions  = new ManagedCuda.VectorTypes.dim3(Resolution / cuda_blockNum, Resolution, 1);
            cuKernel.BlockDimensions = new ManagedCuda.VectorTypes.dim3(cuda_blockNum, 1, 1);

            cuKernel.Run(devData.DevicePointer, copy_devData.DevicePointer, Resolution);

            copy_devData.CopyToHost(result);

            for (i = 0; i < Resolution; i++)
            {
                for (j = 0; j < Resolution; j++)
                {
                    FFTData2D[i, j, 0] = result[i * Resolution + j].x;
                    FFTData2D[i, j, 1] = result[i * Resolution + j].y;
                }
            }

            //Clean up
            devData.Dispose();
            copy_devData.Dispose();
            plan1D.Dispose();
            CudaContext.ProfilerStop();
            ctx.Dispose();
        }
Exemplo n.º 25
0
 /// <summary>
 /// Performs application-defined tasks associated with freeing, releasing, or resetting unmanaged resources.
 /// </summary>
 public void Dispose()
 {
     BlasHandles.Dispose();
     CudaContext.Dispose();
     this.MemoryAllocator.Dispose();
 }
Exemplo n.º 26
0
        public List <float> hypotesis_long_save(List <double> xx, List <double> h, int N)
        {
            int n = (int)Math.Ceiling((double)(xx.Count() + 0.000000000001) / N);

            double[] temp_data = new double[n * (N + h.Count - 1) - (n - 1) * (h.Count - 1)];
            xx.CopyTo(temp_data, h.Count - 1);
            List <double> x = temp_data.ToList();
            //int N = 2000000;

            string      path   = Path.GetDirectoryName(mv.plugins[0].filename);
            CudaContext ctx    = new CudaContext();
            CudaKernel  kernel = ctx.LoadKernel(path + "\\kernel.ptx", "ComplexMultCUDA");

            kernel.GridDimensions  = (int)Math.Ceiling((double)(N + h.Count - 1) / 1024);
            kernel.BlockDimensions = 1024;

            int blocks = (int)Math.Ceiling((double)(x.Count + h.Count - 1) / (N + h.Count - 1));

            double[][] temp_y = new double[n][];
            double[]   temp_h = new double[N + h.Count - 1];
            double[]   temp_x = new double[N + h.Count - 1];


            h.ToArray().CopyTo(temp_h, 0);


            CudaDeviceVariable <double> d_x = null;



            CudaDeviceVariable <double>  d_h = new CudaDeviceVariable <double>(N + h.Count - 1);
            CudaDeviceVariable <double2> d_H = new CudaDeviceVariable <double2>(N + h.Count - 1);

            //CudaDeviceVariable<double> d_y = new CudaDeviceVariable<double>(N + h.Count - 1);


            CudaFFTPlan1D planForward = new CudaFFTPlan1D(N + h.Count - 1, cufftType.D2Z, 1);
            CudaFFTPlan1D planInverse = new CudaFFTPlan1D(N + h.Count - 1, cufftType.Z2D, 1);

            try
            {
                d_h = temp_h;
                planForward.Exec(d_h.DevicePointer, d_H.DevicePointer, TransformDirection.Forward);
            }
            catch (Exception exp)
            {
                mainView.log(exp, "CUDA error: Impulse response FFT", this);
                return(null);
            }


            for (int g = 0; g < n; g++)
            {
                CudaDeviceVariable <double2> d_X = new CudaDeviceVariable <double2>(N + h.Count - 1);
                int P = N + h.Count - 1;
                //if (x.Count - P * g < P) P = x.Count - P * g;
                int L = h.Count - 1;
                if (g == 0)
                {
                    L = 0;
                }

                x.CopyTo(P * g - L * g, temp_x, 0, P);

                try
                {
                    d_x = temp_x;
                    planForward.Exec(d_x.DevicePointer, d_X.DevicePointer);
                    kernel.Run(d_H.DevicePointer, d_X.DevicePointer, N + h.Count - 1);
                    planInverse.Exec(d_X.DevicePointer, d_x.DevicePointer);
                }
                catch (Exception exp)
                {
                    mainView.log(exp, "Cuda error: kernel run cuda error", this);
                }

                temp_y[g] = d_x;
                d_x.Dispose();
                d_X.Dispose();
            }
            planForward.Dispose();
            planInverse.Dispose();
            d_x.Dispose();

            d_h.Dispose();
            d_H.Dispose();
            ctx.Dispose();

            return(OverlapSave(temp_y, h.Count, N + h.Count - 1).GetRange(h.Count / 2, xx.Count));
        }