Esempio n. 1
0
 private static void extractAndLoadNativeLibs() throws IOException {
   Path target = Paths.get(ioTmpDir, "/tklib");
   if (!target.toFile().exists()) {
     Files.createDirectories(target);
   }
   final boolean windows = System.getProperty("os.name").equalsIgnoreCase("windows");
   String fileExtension = windows ? "dll" : "so";
   String prefix = windows ? "" : "lib";
   String libPattern = fileExtension.equals("dll") ? "-windows" : "-linux" + "-x86";
   if (System.getProperty("sun.arch.data.model").equals("64")) {
     libPattern += "_64";
   }
   libPattern += "." + fileExtension;
   //		System.err.println(libPattern);
   System.setProperty("java.library.path", target.toString());
   //		System.err.println(System.getProperty("java.library.path"));
   extractAndLoadNativeLib(prefix + "JCudaDriver" + libPattern, target);
   extractAndLoadNativeLib(prefix + "JCudaRuntime" + libPattern, target);
   extractAndLoadNativeLib(prefix + "JCurand" + libPattern, target);
 }
Esempio n. 2
0
 private static void extractAndLoadNativeLib(String nativeLibName, Path target) {
   //		System.err.println("loading "+nativeLibName);
   final Path path = Paths.get(target.toString(), nativeLibName);
   if (!path.toFile().exists()) {
     try (InputStream is =
         CudaEngine.class
             .getClassLoader()
             .getResourceAsStream("/lib/" + nativeLibName)) { // TODO TK property for lib dir
       Files.copy(is, path);
     } catch (IOException e) {
       e.printStackTrace();
     } catch (NullPointerException e) { // TODO find a way to do it instead of eclipse
       final Path eclipsePath = FileSystems.getDefault().getPath("lib", nativeLibName);
       try {
         Files.copy(eclipsePath, path);
       } catch (IOException e1) {
         // TODO Auto-generated catch block
         e1.printStackTrace();
       }
     }
   }
   System.load(path.toString());
   //		System.load(nativeLibName);
 }
Esempio n. 3
0
public class CudaEngine {

  static final Map<Integer, CudaEngine> cudaEngines = new HashMap<>();
  private static final String PHEROMONES_CU = "pheromones";
  private static final String ioTmpDir = System.getProperty("java.io.tmpdir");
  private static int availableDevicesNb = 0;
  private static ExecutorService initialization;
  private static int NB_OF_DEVICE_TO_USE = 1;
  private static AtomicInteger cudaObjectID = new AtomicInteger(0);
  final HashMap<Kernel, CUfunction> kernels = new HashMap<Kernel, CUfunction>();
  protected CUfunction f;
  protected CUcontext context;
  private ExecutorService exe;
  private List<CudaObject> cudaObjects = new ArrayList<CudaObject>();
  private int maxThreads;
  private int Id = -1;
  private Map<String, CUdeviceptr> neigborsPtrs;

  private CudaEngine(final int deviceId) {
    exe = Executors.newSingleThreadExecutor(); // mandatory: Only one cuda thread per context
    Id = deviceId;
    try {
      exe.submit(
              new Runnable() {
                @Override
                public void run() {
                  CUdevice device = new CUdevice();
                  JCudaDriver.cuDeviceGet(device, deviceId);
                  int array[] = {0};
                  JCudaDriver.cuDeviceGetAttribute(
                      array, CU_DEVICE_ATTRIBUTE_MAX_THREADS_PER_BLOCK, device);
                  maxThreads = (int) Math.sqrt(array[0]);
                  context = new CUcontext();
                  //					JCudaDriver.cuCtxCreate(context, CUctx_flags.CU_CTX_SCHED_BLOCKING_SYNC,
                  // device);
                  JCudaDriver.cuCtxCreate(context, 0, device);
                  CUmodule m = new CUmodule();
                  initModules(m);
                  for (Kernel k : Kernel.values()) {
                    initFunction(m, k);
                  }
                  //					JCudaDriver.cuCtxSetCacheConfig(CUfunc_cache.CU_FUNC_CACHE_PREFER_NONE);>
                  //
                  //	JCudaDriver.cuCtxSetSharedMemConfig(CUsharedconfig.CU_SHARED_MEM_CONFIG_EIGHT_BYTE_BANK_SIZE);
                }
              })
          .get();
    } catch (InterruptedException | ExecutionException e) {
      throw new RuntimeException(e.getMessage());
    }
    neigborsPtrs = new HashMap<>();
  }

  private static void extractAndLoadNativeLib(String nativeLibName, Path target) {
    //		System.err.println("loading "+nativeLibName);
    final Path path = Paths.get(target.toString(), nativeLibName);
    if (!path.toFile().exists()) {
      try (InputStream is =
          CudaEngine.class
              .getClassLoader()
              .getResourceAsStream("/lib/" + nativeLibName)) { // TODO TK property for lib dir
        Files.copy(is, path);
      } catch (IOException e) {
        e.printStackTrace();
      } catch (NullPointerException e) { // TODO find a way to do it instead of eclipse
        final Path eclipsePath = FileSystems.getDefault().getPath("lib", nativeLibName);
        try {
          Files.copy(eclipsePath, path);
        } catch (IOException e1) {
          // TODO Auto-generated catch block
          e1.printStackTrace();
        }
      }
    }
    System.load(path.toString());
    //		System.load(nativeLibName);
  }

  private static void extractAndLoadNativeLibs() throws IOException {
    Path target = Paths.get(ioTmpDir, "/tklib");
    if (!target.toFile().exists()) {
      Files.createDirectories(target);
    }
    final boolean windows = System.getProperty("os.name").equalsIgnoreCase("windows");
    String fileExtension = windows ? "dll" : "so";
    String prefix = windows ? "" : "lib";
    String libPattern = fileExtension.equals("dll") ? "-windows" : "-linux" + "-x86";
    if (System.getProperty("sun.arch.data.model").equals("64")) {
      libPattern += "_64";
    }
    libPattern += "." + fileExtension;
    //		System.err.println(libPattern);
    System.setProperty("java.library.path", target.toString());
    //		System.err.println(System.getProperty("java.library.path"));
    extractAndLoadNativeLib(prefix + "JCudaDriver" + libPattern, target);
    extractAndLoadNativeLib(prefix + "JCudaRuntime" + libPattern, target);
    extractAndLoadNativeLib(prefix + "JCurand" + libPattern, target);
  }

  public static void main(String[] args) {
    init();
  }

  /** */
  public static boolean init() {
    synchronized (cudaEngines) {
      System.err.println("---------Initializing Cuda----------------");
      try {
        extractAndLoadNativeLibs();
        JCudaDriver.setExceptionsEnabled(true);
        JCudaDriver.cuInit(0);
        compileKernelsPtx();
        // Obtain the number of devices
        int deviceCountArray[] = {0};
        JCudaDriver.cuDeviceGetCount(deviceCountArray);
        availableDevicesNb = deviceCountArray[0];
        if (availableDevicesNb == 0) return false;
        availableDevicesNb = NB_OF_DEVICE_TO_USE; // TODO
        initialization = Executors.newCachedThreadPool();
        System.out.println("Found " + availableDevicesNb + " GPU devices");
        for (int i = 0 /*-NB_OF_DEVICE_TO_USE*/; i < availableDevicesNb; i++) {
          final int index = i;
          Future<?> initJob =
              initialization.submit(
                  new Runnable() {
                    public void run() {
                      System.err.println("Initializing device n°" + index);
                      cudaEngines.put(index, new CudaEngine(index));
                    }
                  });
          initJob.get();
          initialization.shutdown();
        }
      } catch (InterruptedException
          | ExecutionException
          | IOException
          | CudaException
          | UnsatisfiedLinkError e) {
        e.printStackTrace();
        System.err.println("---------Cannot initialize Cuda !!! ----------------");
        return false;
      }
      Runtime.getRuntime()
          .addShutdownHook(
              new Thread() {
                @Override
                public void run() {
                  CudaEngine.stop();
                }
              });
      System.out.println("---------Cuda Initialized----------------");
      return true;
    }
  }

  public static boolean isCudaAvailable() {
    return availableDevicesNb != 0;
  }

  public static CudaEngine getCudaEngine(CudaObject co) {
    synchronized (cudaEngines) {
      if (!isCudaAvailable()) throw new CudaException("No cuda device found");
      try {
        initialization.awaitTermination(100, TimeUnit.SECONDS);
      } catch (InterruptedException e) {
        e.printStackTrace();
      }
      Pheromone p = (Pheromone) co;
      final int pheroID = cudaObjectID.incrementAndGet();

      final CudaEngine ce = cudaEngines.get(pheroID % availableDevicesNb);
      //			final CudaEngine ce = cudaEngines.get(1);
      //			final CudaEngine ce = cudaEngines.get(0);

      //			final CudaEngine ce;
      //			if(p.getName().contains("PRE")){
      //				ce = cudaEngines.get(0);
      //			}
      //			else{
      //				ce = cudaEngines.get(1);
      //			}
      //
      ce.cudaObjects.add(co);
      System.err.println(co + "ID " + pheroID + " getting cuda engine Id " + ce.Id);
      return ce;
    }
  }

  static FloatBuffer getUnifiedFloatBuffer(Pointer pinnedMemory, CUdeviceptr devicePtr, long size) {
    JCudaDriver.cuMemHostAlloc(pinnedMemory, size, JCudaDriver.CU_MEMHOSTALLOC_DEVICEMAP);
    final ByteBuffer byteBuffer = pinnedMemory.getByteBuffer(0, size);
    byteBuffer.order(ByteOrder.nativeOrder());
    JCudaDriver.cuMemHostGetDevicePointer(devicePtr, pinnedMemory, 0);
    return byteBuffer.asFloatBuffer();
  }

  public static IntBuffer getUnifiedIntBuffer(
      Pointer pinnedMemory, CUdeviceptr devicePtr, int size) {
    JCudaDriver.cuMemHostAlloc(pinnedMemory, size, JCudaDriver.CU_MEMHOSTALLOC_DEVICEMAP);
    final ByteBuffer byteBuffer = pinnedMemory.getByteBuffer(0, size);
    byteBuffer.order(ByteOrder.nativeOrder());
    JCudaDriver.cuMemHostGetDevicePointer(devicePtr, pinnedMemory, 0);
    return byteBuffer.asIntBuffer();
  }

  public static int[] getUnifiedIntArray(Pointer pinnedMemory, CUdeviceptr devicePtr, int size) {
    int[] values = new int[size];
    JCudaDriver.cuMemHostAlloc(pinnedMemory, size, JCudaDriver.CU_MEMHOSTALLOC_DEVICEMAP);
    final ByteBuffer byteBuffer = pinnedMemory.getByteBuffer(0, size);
    byteBuffer.order(ByteOrder.nativeOrder());
    JCudaDriver.cuMemHostGetDevicePointer(devicePtr, pinnedMemory, 0);

    return values;
  }

  public static ByteBuffer getUnifiedByteBuffer(
      Pointer pinnedMemory, CUdeviceptr devicePtr, int size) {
    JCudaDriver.cuMemHostAlloc(pinnedMemory, size, JCudaDriver.CU_MEMHOSTALLOC_DEVICEMAP);
    final ByteBuffer byteBuffer = pinnedMemory.getByteBuffer(0, size);
    byteBuffer.order(ByteOrder.nativeOrder());
    JCudaDriver.cuMemHostGetDevicePointer(devicePtr, pinnedMemory, 0);
    return byteBuffer;
  }

  /** Stop the executors and clean memory on registered CUObject */
  public static void stop() {
    synchronized (cudaEngines) {
      cuCtxSynchronizeAll();
      for (Iterator<CudaEngine> iterator = cudaEngines.values().iterator(); iterator.hasNext(); ) {
        iterator.next().shutdown();
        iterator.remove();
      }
      //		for (CudaEngine ce : cudaEngines.values()) {
      //			ce.shutdown();
      //		}
    }
  }

  /** Stop the executors and clean memory on registered CUObject */
  public static synchronized void freeMemory() {
    for (CudaEngine ce : cudaEngines.values()) {
      ce.freeCUObjectsMemory();
    }
  }

  static void initModules(CUmodule module) {
    JCudaDriver.cuModuleLoad(module, new File(ioTmpDir, PHEROMONES_CU + ".ptx").getAbsolutePath());
  }

  // void compileKernelsPtx()
  static void compileKernelsPtx() throws IOException {
    if (!new File(ioTmpDir, PHEROMONES_CU + ".ptx").exists()) { // TODO externalize
      try (InputStream is =
          CudaEngine.class.getResourceAsStream(
              "/turtlekit/cuda/kernels/" + PHEROMONES_CU + ".cu")) {
        final Path path = Paths.get(ioTmpDir, PHEROMONES_CU + ".cu");
        try {
          Files.copy(is, path);
        } catch (FileAlreadyExistsException e) {
        }
        System.err.println("--------------- Compiling ptx ----------------------");
        KernelLauncher.create(
            path.toString(),
            Kernel.DIFFUSION_TO_TMP.name(),
            false,
            "--use_fast_math",
            "--prec-div=false"); // ,"--gpu-architecture=sm_20");
      } catch (IOException e) {
        throw e;
      }
    }
  }

  public static synchronized void cuCtxSynchronizeAll() {
    for (CudaEngine ce : cudaEngines.values()) {
      ce.cuCtxSynchronize();
    }
    // List<Future<Void>> futures = new ArrayList<Future<Void>>();
    // for (CudaEngine ce : executors) {
    // futures.add(ce.exe.submit(new Callable<Void>() {
    // @Override
    // public Void call() throws Exception {
    // JCudaDriver.cuCtxSynchronize();
    // return null;
    // }
    //
    // }));
    // }
    // for (Future<Void> future : futures) {
    // try {
    // future.get();
    // } catch (InterruptedException | ExecutionException e) {
    // // TODO Auto-generated catch block
    // e.printStackTrace();
    // }
    // }
  }

  public int cuDeviceGetCount() {
    return availableDevicesNb;
  }

  /** Free memory from the currently registered CUObjects */
  public void freeCUObjectsMemory() {
    exe.submit(
        new Runnable() {
          @Override
          public void run() {
            cuCtxSynchronize();
            for (CudaObject co : cudaObjects) {
              co.freeMemory();
            }
            JCudaDriver.cuCtxDestroy(context);
          }
        });
  }

  private synchronized void shutdown() {
    if (!exe.isShutdown()) {
      freeCUObjectsMemory();
    }
    exe.shutdown();
    try {
      System.err.println(
          "cuda device " + Id + " freed ? " + exe.awaitTermination(10, TimeUnit.SECONDS));
    } catch (InterruptedException e) {
      e.printStackTrace();
    }
  }

  private void initFunction(CUmodule module, Kernel name) {
    CUfunction function = new CUfunction();
    JCudaDriver.cuModuleGetFunction(function, module, name.name());
    kernels.put(name, function);
  }

  public int getMaxThreads() {
    return maxThreads;
  }

  public CUfunction getKernelFunction(Kernel f) {
    CUfunction function = kernels.get(f);
    if (function == null) throw new CudaException("No such function " + f);
    return function;
  }

  //	public static void main(String[] args) {
  //		CudaPheromone cu, cu2;
  //		getCudaEngine(cu = new CudaPheromone(10, 10, 0.1f, 0f, "test"));
  //		getCudaEngine(cu2 = new CudaPheromone(100, 100, 0.3f, 0.5f, "test2"));
  //		cu.set(3, 3, 8);
  ////		cu.diffusion();
  //		cu.evaporation();
  //		System.err.println(cu.get(3, 3));
  //		System.err.println(cu.get(0, 0));
  //		System.err.println(cu.get(3, 2));
  //		System.err.println("maxdir " + cu.getMaxDir(3, 2));
  //		cu.diffusion();
  //		System.err.println(cu.get(3, 3));
  //		cu.diffusion();
  //		System.err.println(cu.get(3, 3));
  //		cu2.diffusion();
  //		cu.freeMemory();
  //		cu2.freeMemory();
  //		CudaEngine.stop();
  //	}

  public void cuCtxSynchronize() {
    try {
      exe.submit(
              new Callable<Void>() {
                @Override
                public Void call() throws Exception {
                  JCudaDriver.cuCtxSynchronize();
                  return null;
                }
              })
          .get();
    } catch (InterruptedException | ExecutionException e) {
      e.printStackTrace();
    }
  }

  public Future<?> submit(Runnable runnable) {
    if (!exe.isShutdown()) {
      return exe.submit(runnable);
    }
    return null;
  }

  public CUdeviceptr getNeighborsPtr(String string) {
    return neigborsPtrs.get(string);
  }

  public void addNeighborsPtr(String string, CUdeviceptr neighborsPtr) {
    neigborsPtrs.put(string, neighborsPtr);
  }

  enum Kernel {
    DIFFUSION_TO_TMP,
    DIFFUSION_UPDATE,
    EVAPORATION,
    FIELD_MAX_DIR,
    DIFFUSION_UPDATE_THEN_EVAPORATION,
    DIFFUSION_UPDATE_THEN_EVAPORATION_THEN_FIELDMAXDIR
    //		,FILL_NEIGHBORS
    ,
    TEST,
    DIFFUSION_UPDATE_THEN_EVAPORATION_THEN_FIELDMAXDIRV2
  }
}