public static void ReturnFinder(CGraph finder)
{
if (finders.Count < 10)
{
finders.Add(finder);
}
}
public static void RunFinder(bool TEST, ref int trims, uint edgesCount, int[] edgesLeft, Job currentJob, ConcurrentQueue <Solution> graphSolutions, Stopwatch sw)
{
CGraph cg = GetFinder();
cg.SetEdges(edgesLeft, (int)edgesCount);
cg.SetHeader(currentJob);
var cancellationTokenSource = new CancellationTokenSource(TimeSpan.FromMilliseconds(500));
var finder = Task.Factory.StartNew(() =>
{
try
{
if (edgesCount < 120000)
{
if (cg.edges.Count(e => e == 0) > 100)
{
//Console.ForegroundColor = ConsoleColor.Red;
//Console.WriteLine("edges corrupted");
//Console.ResetColor();
return;
}
if (findersInFlight++ < 3)
{
Stopwatch cycleTime = new Stopwatch();
cycleTime.Start();
cg.FindSolutions(graphSolutions);
cycleTime.Stop();
AdjustTrims(cycleTime.ElapsedMilliseconds);
if (TEST)
{
Logger.Log(LogLevel.Info, string.Format("Finder completed in {0}ms on {1} edges with {2} solution(s) and {3} dupes", sw.ElapsedMilliseconds, edgesCount, graphSolutions.Count, cg.dupes));
}
}
else
{
Logger.Log(LogLevel.Warning, string.Format("CPU overloaded / {0}ms on {1} edges", sw.ElapsedMilliseconds, edgesCount));
}
}
}
catch (Exception ex)
{
Logger.Log(LogLevel.Warning, "Cycle finder crashed " + ex.Message);
}
finally
{
ReturnFinder(cg);
}
}, cancellationTokenSource.Token);
//Task.Delay(2000).ContinueWith((t) => {
// if (finder != null && finder.Status != TaskStatus.RanToCompletion)
// {
// File.AppendAllText("overload.txt", $"{DateTime.Now.ToString()}: thread killed");
// finder.Dispose();
// }
//});
}
private static void ReturnFinder(CGraph finder)
{
findersInFlight--;
if (finders.Count < 10)
{
finders.Add(finder);
}
}
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 { }
}
