Exemplo n.º 1
0
  public Grid2D adding() {
    long start = System.nanoTime();

    for (int i = 0; i < 1000; i++) {
      NumericPointwiseOperators.addedBy(image, image);
    }
    long end = System.nanoTime();

    System.out.println("Time difference " + ((end - start) / 1e6) + " ms");

    Grid2D result = new Grid2D(image);
    return result;
  }
Exemplo n.º 2
0
  public void iterativeReconstruct() throws Exception {

    Grid3D r = InitializeProjectionViews();
    Grid3D q = InitializeProjectionViews();
    Grid3D f = InitializeVolumeImage();
    Grid3D d = InitializeVolumeImage();
    Grid3D g_new = InitializeVolumeImage();
    Grid3D g_old = InitializeVolumeImage();

    double gamma;
    double alpha;

    NumericPointwiseOperators.copy(projectionViews, r);

    System.out.print(
        "Model-based iterative reconstruction using least-squares conjugate gradient solver: \n");
    System.out.print("itn   \t||r||  \t\t  x(0) \t\n");
    System.out.print("---------------------------------------- \n");

    for (int itr = 1; itr <= maxNumOfIterations; itr++) {

      if (itr <= 5 || itr % 10 == 0 || itr >= maxNumOfIterations - 5)
        System.out.print(
            itr
                + "  \t"
                + String.format("%8.3g", NumericPointwiseOperators.dotProduct(r))
                + " \t"
                + String.format("%8.4f", f.getAtIndex(maxJ / 2, maxK / 2, maxK / 2))
                + " \n");

      backproject(r, g_new);

      if (itr == 1) {
        gamma = 0.0;
        NumericPointwiseOperators.copy(g_new, d);
      } else {
        gamma =
            NumericPointwiseOperators.dotProduct(g_new)
                / NumericPointwiseOperators.dotProduct(g_old);
        NumericPointwiseOperators.multiplyBy(d, (float) gamma);
        NumericPointwiseOperators.addBy(d, g_new);
      }

      forwardproject(q, d);

      alpha =
          NumericPointwiseOperators.dotProduct(g_new, d) / NumericPointwiseOperators.dotProduct(q);

      NumericGrid tmp = d.clone();
      NumericPointwiseOperators.multiplyBy(tmp, (float) alpha);
      NumericPointwiseOperators.addBy(f, tmp);

      tmp = q.clone();
      NumericPointwiseOperators.multiplyBy(tmp, (float) -alpha);
      NumericPointwiseOperators.addBy(r, tmp);

      NumericPointwiseOperators.copy(g_new, g_old);
    }
    volumeImage = f;
  }
Exemplo n.º 3
0
  private synchronized void projectSingleProjection(int projectionNumber, int dimz) {
    // load projection matrix
    initProjectionMatrix(projectionNumber);
    // load projection
    Grid2D projection = (Grid2D) projections.get(projectionNumber).clone();
    // Correct for constant part of distance weighting + For angular sampling
    double D = getGeometry().getSourceToDetectorDistance();
    NumericPointwiseOperators.multiplyBy(
        projection, (float) (D * D * 2 * Math.PI / getGeometry().getNumProjectionMatrices()));

    initProjectionData(projection);
    if (!largeVolumeMode) {
      projections.remove(projectionNumber);
    }
    // backproject for each slice
    // CUDA Grids are only two dimensional!
    int[] zed = new int[1];
    int reconDimensionZ = dimz;
    double voxelSpacingX = getGeometry().getVoxelSpacingX();
    double voxelSpacingY = getGeometry().getVoxelSpacingY();
    double voxelSpacingZ = getGeometry().getVoxelSpacingZ();

    zed[0] = reconDimensionZ;
    Pointer dOut = Pointer.to(volumePointer);
    Pointer pWidth = Pointer.to(new int[] {(int) lineOffset});
    Pointer pZOffset = Pointer.to(zed);
    float[] vsx = new float[] {(float) voxelSpacingX};
    Pointer pvsx = Pointer.to(vsx);
    Pointer pvsy = Pointer.to(new float[] {(float) voxelSpacingY});
    Pointer pvsz = Pointer.to(new float[] {(float) voxelSpacingZ});
    Pointer pox = Pointer.to(new float[] {(float) offsetX});
    Pointer poy = Pointer.to(new float[] {(float) offsetY});
    Pointer poz = Pointer.to(new float[] {(float) offsetZ});

    int offset = 0;
    // System.out.println(dimz + " " + zed[0] + " " + offsetZ + " " + voxelSpacingZ);
    offset = CUDAUtil.align(offset, Sizeof.POINTER);
    JCudaDriver.cuParamSetv(function, offset, dOut, Sizeof.POINTER);
    offset += Sizeof.POINTER;

    offset = CUDAUtil.align(offset, Sizeof.INT);
    JCudaDriver.cuParamSetv(function, offset, pWidth, Sizeof.INT);
    offset += Sizeof.INT;

    offset = CUDAUtil.align(offset, Sizeof.INT);
    JCudaDriver.cuParamSetv(function, offset, pZOffset, Sizeof.INT);
    offset += Sizeof.INT;

    offset = CUDAUtil.align(offset, Sizeof.FLOAT);
    JCudaDriver.cuParamSetv(function, offset, pvsx, Sizeof.FLOAT);
    offset += Sizeof.FLOAT;

    offset = CUDAUtil.align(offset, Sizeof.FLOAT);
    JCudaDriver.cuParamSetv(function, offset, pvsy, Sizeof.FLOAT);
    offset += Sizeof.FLOAT;

    offset = CUDAUtil.align(offset, Sizeof.FLOAT);
    JCudaDriver.cuParamSetv(function, offset, pvsz, Sizeof.FLOAT);
    offset += Sizeof.FLOAT;

    offset = CUDAUtil.align(offset, Sizeof.FLOAT);
    JCudaDriver.cuParamSetv(function, offset, pox, Sizeof.FLOAT);
    offset += Sizeof.FLOAT;

    offset = CUDAUtil.align(offset, Sizeof.FLOAT);
    JCudaDriver.cuParamSetv(function, offset, poy, Sizeof.FLOAT);
    offset += Sizeof.FLOAT;

    offset = CUDAUtil.align(offset, Sizeof.FLOAT);
    JCudaDriver.cuParamSetv(function, offset, poz, Sizeof.FLOAT);
    offset += Sizeof.FLOAT;

    JCudaDriver.cuParamSetSize(function, offset);

    // Call the CUDA kernel, writing the results into the volume which is pointed at
    JCudaDriver.cuFuncSetBlockShape(function, bpBlockSize[0], bpBlockSize[1], 1);
    JCudaDriver.cuLaunchGrid(function, gridSize.x, gridSize.y);
    JCudaDriver.cuCtxSynchronize();
  }