/** * Calculates length of a given phrase on the grid. * * @param phrase Phrase to count the number of letters in. * @throws GridException If failed. */ private static void countLettersReducer(String phrase) throws GridException { X.println(">>> Starting countLettersReducer() example..."); Grid grid = G.grid(); // Logger to use in your closure. Note that even though we assign it // to a local variable, GridGain still allows to use it from remotely // executed code. final GridLogger log = grid.log(); // Execute Hello World task. int letterCnt = grid.reduce( BALANCE, new GridClosure<String, Integer>() { // Create executable logic. @Override public Integer apply(String word) { // Print out a given word, just so we can // see which node is doing what. log.info(">>> Calculating for word: " + word); // Return the length of a given word, i.e. number of letters. return word.length(); } }, Arrays.asList(phrase.split(" ")), // Collection of words. // Create custom reducer. // NOTE: Alternatively, you can use existing reducer: F.sumIntReducer() new GridReducer<Integer, Integer>() { private int sum; @Override public boolean collect(Integer res) { sum += res; return true; // True means continue collecting until last result. } @Override public Integer apply() { return sum; } }); X.println(">>>"); X.println(">>> Finished execution of counting letters with reducer based on GridGain 3.0 API."); X.println(">>> Total number of letters in the phrase is '" + letterCnt + "'."); X.println(">>> You should see individual words printed out on different nodes."); X.println(">>> Check all nodes for output (this node is also part of the grid)."); X.println(">>>"); }
/** * @param args Command arguments. * @throws GridException If failed. */ public static void main(String[] args) throws GridException { // Starts grid. Grid grid = args.length == 0 ? G.start() : G.start(args[0]); try { // Create portfolio. GridCredit[] portfolio = new GridCredit[5000]; Random rnd = new Random(); // Generate some test portfolio items. for (int i = 0; i < portfolio.length; i++) { portfolio[i] = new GridCredit( 50000 * rnd.nextDouble(), // Credit amount. rnd.nextInt(1000), // Credit term in days. rnd.nextDouble() / 10, // APR. rnd.nextDouble() / 20 + 0.02 // EDF. ); } // Forecast horizon in days. int horizon = 365; // Number of Monte-Carlo iterations. int iter = 10000; // Percentile. double percentile = 0.95; // Mark the stopwatch. long start = System.currentTimeMillis(); // Calculate credit risk and print it out. // As you can see the grid enabling is completely hidden from the caller // and it is fully transparent to him. In fact, the caller is never directly // aware if method was executed just locally or on the 100s of grid nodes. // Credit risk crdRisk is the minimal amount that creditor has to have // available to cover possible defaults. double crdRisk = grid.reduce( SPREAD, closures(grid.size(), portfolio, horizon, iter, percentile), new R1<Double, Double>() { /** Collected values sum. */ private double sum; /** Collected values count. */ private int count; /** {@inheritDoc} */ @Override public boolean collect(Double e) { sum += e; count++; return true; } /** {@inheritDoc} */ @Override public Double apply() { return sum / count; } }); X.println( "Credit risk [crdRisk=" + crdRisk + ", duration=" + (System.currentTimeMillis() - start) + "ms]"); } // We specifically don't do any error handling here to // simplify the example. Real application may want to // add error handling and application specific recovery. finally { // Stops grid. G.stop(true); } }