test/loops/CCJacobi.java

/*
 * Written by Doug Lea with assistance from members of JCP JSR-166
 * Expert Group and released to the public domain, as explained at
 * http://creativecommons.org/publicdomain/zero/1.0/
 */

// Jacobi iteration on a mesh. Based loosely on a Filaments demo

import java.util.concurrent.*;

public class CCJacobi {

    //    static final int DEFAULT_GRANULARITY = 4096;
    static final int DEFAULT_GRANULARITY = 256;

    /**
     * The maximum number of matrix cells
     * at which to stop recursing down and instead directly update.
     */
    static final double EPSILON = 0.0001;  // convergence criterion

    public static void main(String[] args) throws Exception {
        int n = 2048;
        int steps = 1000;
        int granularity = DEFAULT_GRANULARITY;

        try {
            if (args.length > 0)
                n = Integer.parseInt(args[0]);
            if (args.length > 1)
                steps = Integer.parseInt(args[1]);
            if (args.length > 2)
                granularity = Integer.parseInt(args[2]);
        }

        catch (Exception e) {
            System.out.println("Usage: java FJJacobi <matrix size> <max steps> [<leafcells>]");
            return;
        }

        ForkJoinPool fjp = new ForkJoinPool();

        // 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 = EPSILON; // 1.0/dim;
        for (int i = 1; i < dim-1; ++i) {
            for (int j = 1; j < dim-1; ++j)
                a[i][j] = smallVal;
        }
        // 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;
            b[k][0] = 1.0;
            b[k][n+1] = 1.0;
            b[0][k] = 1.0;
            b[n+1][k] = 1.0;
        }
        int nreps = 10;
        for (int rep = 0; rep < nreps; ++rep) {
            Driver driver = new Driver(a, b, 1, n, 1, n, steps, granularity);

            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);
        }
    }


    abstract static class MatrixTree extends CountedCompleter {
        // maximum difference between old and new values
        double maxDiff;
        MatrixTree(CountedCompleter p, int c) { super(p, c); }
    }


    static final class LeafNode extends MatrixTree {
        final double[][] A; // matrix to get old values from
        final double[][] B; // matrix to put new values into

        // indices of current submatrix
        final int loRow;    final int hiRow;
        final int loCol;    final int hiCol;

        int steps = 0; // track even/odd steps

        LeafNode(CountedCompleter p,
                 double[][] A, double[][] B,
                 int loRow, int hiRow,
                 int loCol, int hiCol) {
            super(p, 0);
            this.A = A;   this.B = B;
            this.loRow = loRow; this.hiRow = hiRow;
            this.loCol = loCol; this.hiCol = hiCol;
        }

        public final void compute() {
            boolean AtoB = (steps++ & 1) == 0;
            double[][] a = AtoB ? A : B;
            double[][] b = AtoB ? B : A;

            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;
                }
            }

            maxDiff = md;
            tryComplete(); 
        }
    }

    static final class FourNode extends MatrixTree {
        MatrixTree q1;
        MatrixTree q2;
        MatrixTree q3;
        MatrixTree q4;
        FourNode(CountedCompleter p) {
            super(p, 3);
        }

        public void onCompletion(CountedCompleter caller) {
            double md = q1.maxDiff, m;
            if ((m = q2.maxDiff) > md)
                md = m;
            if ((m = q3.maxDiff) > md)
                md = m;
            if ((m = q4.maxDiff) > md)
                md = m;
            maxDiff = md;
            setPendingCount(3);
        }

        public final void compute() {
            q4.fork();
            q3.fork();
            q2.fork();
            q1.compute();
        }
    }


    static final class TwoNode extends MatrixTree {
        MatrixTree q1;
        MatrixTree q2;

        TwoNode(CountedCompleter p) {
            super(p, 1);
        }

        public void onCompletion(CountedCompleter caller) {
            double md = q1.maxDiff, m;
            if ((m = q2.maxDiff) > md)
                md = m;
            maxDiff = md;
            setPendingCount(1);
        }

        public final void compute() {
            q2.fork();
            q1.compute();
        }

    }

    static final class Driver extends RecursiveAction {
        MatrixTree mat;
        double[][] A; double[][] B;
        int firstRow; int lastRow;
        int firstCol; int lastCol;
        final int steps;
        final int leafs;
        int nleaf;

        Driver(double[][] A, double[][] B,
               int firstRow, int lastRow,
               int firstCol, int lastCol,
               int steps, int leafs) {
            this.A = A;
            this.B = B;
            this.firstRow = firstRow;
            this.firstCol = firstCol;
            this.lastRow = lastRow;
            this.lastCol = lastCol;
            this.steps = steps;
            this.leafs = leafs;
            mat = build(null, A, B, firstRow, lastRow, firstCol, lastCol, leafs);
            System.out.println("Using " + nleaf + " segments");

        }

        MatrixTree build(MatrixTree p,
                         double[][] a, double[][] b,
                         int lr, int hr, int lc, int hc, int leafs) {
            int rows = (hr - lr + 1);
            int cols = (hc - lc + 1);

            int mr = (lr + hr) >>> 1; // midpoints
            int mc = (lc + hc) >>> 1;

            int hrows = (mr - lr + 1);
            int hcols = (mc - lc + 1);

            if (rows * cols <= leafs) {
                ++nleaf;
                return new LeafNode(p, a, b, lr, hr, lc, hc);
            }
            else if (hrows * hcols >= leafs) {
                FourNode q = new FourNode(p);
                q.q1 = build(q, a, b, lr,   mr, lc,   mc, leafs);
                q.q2 = build(q, a, b, lr,   mr, mc+1, hc, leafs);
                q.q3 = build(q, a, b, mr+1, hr, lc,   mc, leafs);
                q.q4 = build(q, a, b, mr+1, hr, mc+1, hc, leafs);
                return q;
            }
            else if (cols >= rows) {
                TwoNode q = new TwoNode(p);
                q.q1 = build(q, a, b, lr, hr, lc,   mc, leafs);
                q.q2 = build(q, a, b, lr, hr, mc+1, hc, leafs);
                return q;
            }
            else {
                TwoNode q = new TwoNode(p);
                q.q1 = build(q, a, b, lr,   mr, lc, hc, leafs);
                q.q2 = build(q, a, b, mr+1, hr, lc, hc, leafs);
                return q;
            }
        }

        static void doCompute(MatrixTree m, int s) {
            for (int i = 0; i < s; ++i) {
                m.setPendingCount(3);
                m.invoke();
                m.reinitialize();
            }
        }

        public void compute() {
            doCompute(mat, steps);
            double md = mat.maxDiff;
            System.out.println("max diff after " + steps + " steps = " + md);
        }
    }


}
Revision:	1.1
Committed:	Mon Apr 9 13:18:06 2012 UTC (12 years ago) by dl
Branch:	MAIN
Log Message:	Add tests/demos for CountedCompleters
#	Content
1	/*
2	* Written by Doug Lea with assistance from members of JCP JSR-166
3	* Expert Group and released to the public domain, as explained at
4	* http://creativecommons.org/publicdomain/zero/1.0/
5	*/
6
7	// Jacobi iteration on a mesh. Based loosely on a Filaments demo
8
9	import java.util.concurrent.*;
10
11	public class CCJacobi {
12
13	// static final int DEFAULT_GRANULARITY = 4096;
14	static final int DEFAULT_GRANULARITY = 256;
15
16	/**
17	* The maximum number of matrix cells
18	* at which to stop recursing down and instead directly update.
19	*/
20	static final double EPSILON = 0.0001; // convergence criterion
21
22	public static void main(String[] args) throws Exception {
23	int n = 2048;
24	int steps = 1000;
25	int granularity = DEFAULT_GRANULARITY;
26
27	try {
28	if (args.length > 0)
29	n = Integer.parseInt(args[0]);
30	if (args.length > 1)
31	steps = Integer.parseInt(args[1]);
32	if (args.length > 2)
33	granularity = Integer.parseInt(args[2]);
34	}
35
36	catch (Exception e) {
37	System.out.println("Usage: java FJJacobi <matrix size> <max steps> [<leafcells>]");
38	return;
39	}
40
41	ForkJoinPool fjp = new ForkJoinPool();
42
43	// allocate enough space for edges
44	int dim = n+2;
45	int ncells = dim * dim;
46	double[][] a = new double[dim][dim];
47	double[][] b = new double[dim][dim];
48	// Initialize interiors to small value
49	double smallVal = EPSILON; // 1.0/dim;
50	for (int i = 1; i < dim-1; ++i) {
51	for (int j = 1; j < dim-1; ++j)
52	a[i][j] = smallVal;
53	}
54	// Fill all edges with 1's.
55	for (int k = 0; k < dim; ++k) {
56	a[k][0] = 1.0;
57	a[k][n+1] = 1.0;
58	a[0][k] = 1.0;
59	a[n+1][k] = 1.0;
60	b[k][0] = 1.0;
61	b[k][n+1] = 1.0;
62	b[0][k] = 1.0;
63	b[n+1][k] = 1.0;
64	}
65	int nreps = 10;
66	for (int rep = 0; rep < nreps; ++rep) {
67	Driver driver = new Driver(a, b, 1, n, 1, n, steps, granularity);
68
69	long startTime = System.currentTimeMillis();
70	fjp.invoke(driver);
71
72	long time = System.currentTimeMillis() - startTime;
73	double secs = ((double)time) / 1000.0;
74
75	System.out.println("Compute Time: " + secs);
76	System.out.println(fjp);
77	}
78	}
79
80
81	abstract static class MatrixTree extends CountedCompleter {
82	// maximum difference between old and new values
83	double maxDiff;
84	MatrixTree(CountedCompleter p, int c) { super(p, c); }
85	}
86
87
88	static final class LeafNode extends MatrixTree {
89	final double[][] A; // matrix to get old values from
90	final double[][] B; // matrix to put new values into
91
92	// indices of current submatrix
93	final int loRow; final int hiRow;
94	final int loCol; final int hiCol;
95
96	int steps = 0; // track even/odd steps
97
98	LeafNode(CountedCompleter p,
99	double[][] A, double[][] B,
100	int loRow, int hiRow,
101	int loCol, int hiCol) {
102	super(p, 0);
103	this.A = A; this.B = B;
104	this.loRow = loRow; this.hiRow = hiRow;
105	this.loCol = loCol; this.hiCol = hiCol;
106	}
107
108	public final void compute() {
109	boolean AtoB = (steps++ & 1) == 0;
110	double[][] a = AtoB ? A : B;
111	double[][] b = AtoB ? B : A;
112
113	double md = 0.0; // local for computing max diff
114
115	for (int i = loRow; i <= hiRow; ++i) {
116	for (int j = loCol; j <= hiCol; ++j) {
117	double v = 0.25 * (a[i-1][j] + a[i][j-1] +
118	a[i+1][j] + a[i][j+1]);
119	b[i][j] = v;
120
121	double diff = v - a[i][j];
122	if (diff < 0) diff = -diff;
123	if (diff > md) md = diff;
124	}
125	}
126
127	maxDiff = md;
128	tryComplete();
129	}
130	}
131
132	static final class FourNode extends MatrixTree {
133	MatrixTree q1;
134	MatrixTree q2;
135	MatrixTree q3;
136	MatrixTree q4;
137	FourNode(CountedCompleter p) {
138	super(p, 3);
139	}
140
141	public void onCompletion(CountedCompleter caller) {
142	double md = q1.maxDiff, m;
143	if ((m = q2.maxDiff) > md)
144	md = m;
145	if ((m = q3.maxDiff) > md)
146	md = m;
147	if ((m = q4.maxDiff) > md)
148	md = m;
149	maxDiff = md;
150	setPendingCount(3);
151	}
152
153	public final void compute() {
154	q4.fork();
155	q3.fork();
156	q2.fork();
157	q1.compute();
158	}
159	}
160
161
162	static final class TwoNode extends MatrixTree {
163	MatrixTree q1;
164	MatrixTree q2;
165
166	TwoNode(CountedCompleter p) {
167	super(p, 1);
168	}
169
170	public void onCompletion(CountedCompleter caller) {
171	double md = q1.maxDiff, m;
172	if ((m = q2.maxDiff) > md)
173	md = m;
174	maxDiff = md;
175	setPendingCount(1);
176	}
177
178	public final void compute() {
179	q2.fork();
180	q1.compute();
181	}
182
183	}
184
185	static final class Driver extends RecursiveAction {
186	MatrixTree mat;
187	double[][] A; double[][] B;
188	int firstRow; int lastRow;
189	int firstCol; int lastCol;
190	final int steps;
191	final int leafs;
192	int nleaf;
193
194	Driver(double[][] A, double[][] B,
195	int firstRow, int lastRow,
196	int firstCol, int lastCol,
197	int steps, int leafs) {
198	this.A = A;
199	this.B = B;
200	this.firstRow = firstRow;
201	this.firstCol = firstCol;
202	this.lastRow = lastRow;
203	this.lastCol = lastCol;
204	this.steps = steps;
205	this.leafs = leafs;
206	mat = build(null, A, B, firstRow, lastRow, firstCol, lastCol, leafs);
207	System.out.println("Using " + nleaf + " segments");
208
209	}
210
211	MatrixTree build(MatrixTree p,
212	double[][] a, double[][] b,
213	int lr, int hr, int lc, int hc, int leafs) {
214	int rows = (hr - lr + 1);
215	int cols = (hc - lc + 1);
216
217	int mr = (lr + hr) >>> 1; // midpoints
218	int mc = (lc + hc) >>> 1;
219
220	int hrows = (mr - lr + 1);
221	int hcols = (mc - lc + 1);
222
223	if (rows * cols <= leafs) {
224	++nleaf;
225	return new LeafNode(p, a, b, lr, hr, lc, hc);
226	}
227	else if (hrows * hcols >= leafs) {
228	FourNode q = new FourNode(p);
229	q.q1 = build(q, a, b, lr, mr, lc, mc, leafs);
230	q.q2 = build(q, a, b, lr, mr, mc+1, hc, leafs);
231	q.q3 = build(q, a, b, mr+1, hr, lc, mc, leafs);
232	q.q4 = build(q, a, b, mr+1, hr, mc+1, hc, leafs);
233	return q;
234	}
235	else if (cols >= rows) {
236	TwoNode q = new TwoNode(p);
237	q.q1 = build(q, a, b, lr, hr, lc, mc, leafs);
238	q.q2 = build(q, a, b, lr, hr, mc+1, hc, leafs);
239	return q;
240	}
241	else {
242	TwoNode q = new TwoNode(p);
243	q.q1 = build(q, a, b, lr, mr, lc, hc, leafs);
244	q.q2 = build(q, a, b, mr+1, hr, lc, hc, leafs);
245	return q;
246	}
247	}
248
249	static void doCompute(MatrixTree m, int s) {
250	for (int i = 0; i < s; ++i) {
251	m.setPendingCount(3);
252	m.invoke();
253	m.reinitialize();
254	}
255	}
256
257	public void compute() {
258	doCompute(mat, steps);
259	double md = mat.maxDiff;
260	System.out.println("max diff after " + steps + " steps = " + md);
261	}
262	}
263
264
265	}