// Barrier version of Jacobi iteration import java.util.concurrent.*; public class FJPhaserJacobi { static int dimGran; static final double EPSILON = 0.0001; // convergence criterion public static void main(String[] args) { int n = 2048; int steps = 1000; try { if (args.length > 0) n = Integer.parseInt(args[0]); if (args.length > 1) steps = Integer.parseInt(args[1]); } catch (Exception e) { System.out.println("Usage: java ThreadPhaserJacobi "); return; } ForkJoinPool fjp = new ForkJoinPool(); // int granularity = (n * n / fjp.getParallelism()) / 2; int granularity = n * n / fjp.getParallelism(); dimGran = (int)(Math.sqrt(granularity)); // allocate enough space for edges int dim = n+2; int ncells = dim * dim; double[][] a = new double[dim][dim]; double[][] b = new double[dim][dim]; // Initialize interiors to small value double smallVal = 1.0/dim; for (int i = 1; i < dim-1; ++i) { for (int j = 1; j < dim-1; ++j) a[i][j] = smallVal; } int nreps = 3; for (int rep = 0; rep < nreps; ++rep) { // Fill all edges with 1's. for (int k = 0; k < dim; ++k) { a[k][0] += 1.0; a[k][n+1] += 1.0; a[0][k] += 1.0; a[n+1][k] += 1.0; } Driver driver = new Driver(a, b, 1, n, 1, n, steps); long startTime = System.currentTimeMillis(); fjp.invoke(driver); long time = System.currentTimeMillis() - startTime; double secs = ((double)time) / 1000.0; System.out.println("Compute Time: " + secs); System.out.println(fjp); } } static class Segment extends CyclicAction { double[][] A; // matrix to get old values from double[][] B; // matrix to put new values into // indices of current submatrix final int loRow; final int hiRow; final int loCol; final int hiCol; volatile double maxDiff; // maximum difference between old and new values Segment(double[][] A, double[][] B, int loRow, int hiRow, int loCol, int hiCol, Phaser br) { super(br); this.A = A; this.B = B; this.loRow = loRow; this.hiRow = hiRow; this.loCol = loCol; this.hiCol = hiCol; } public void step() { maxDiff = update(A, B); double[][] tmp = A; A = B; B = tmp; } double update(double[][] a, double[][] b) { double md = 0.0; // local for computing max diff for (int i = loRow; i <= hiRow; ++i) { for (int j = loCol; j <= hiCol; ++j) { double v = 0.25 * (a[i-1][j] + a[i][j-1] + a[i+1][j] + a[i][j+1]); b[i][j] = v; double diff = v - a[i][j]; if (diff < 0) diff = -diff; if (diff > md) md = diff; } } return md; } } static class MyPhaser extends Phaser { final int max; MyPhaser(int steps) { this.max = steps - 1; } public boolean onAdvance(int phase, int registeredParties) { return phase >= max || registeredParties <= 0; } } static class Driver extends RecursiveAction { double[][] A; // matrix to get old values from double[][] B; // matrix to put new values into final int loRow; // indices of current submatrix final int hiRow; final int loCol; final int hiCol; final int steps; Driver(double[][] mat1, double[][] mat2, int firstRow, int lastRow, int firstCol, int lastCol, int steps) { this.A = mat1; this.B = mat2; this.loRow = firstRow; this.hiRow = lastRow; this.loCol = firstCol; this.hiCol = lastCol; this.steps = steps; } public void compute() { int rows = hiRow - loRow + 1; int cols = hiCol - loCol + 1; int rblocks = (int)(Math.round((float)rows / dimGran)); int cblocks = (int)(Math.round((float)cols / dimGran)); int n = rblocks * cblocks; System.out.println("Using " + n + " segments"); Segment[] segs = new Segment[n]; Phaser barrier = new MyPhaser(steps); int k = 0; for (int i = 0; i < rblocks; ++i) { int lr = loRow + i * dimGran; int hr = lr + dimGran; if (i == rblocks-1) hr = hiRow; for (int j = 0; j < cblocks; ++j) { int lc = loCol + j * dimGran; int hc = lc + dimGran; if (j == cblocks-1) hc = hiCol; segs[k] = new Segment(A, B, lr, hr, lc, hc, barrier); ++k; } } invokeAll(segs); double maxd = 0; for (k = 0; k < n; ++k) { double md = segs[k].maxDiff; if (md > maxd) maxd = md; } System.out.println("Max diff after " + steps + " steps = " + maxd); } } }