2 Dimensions

src/main/java/it/polimi/middleware/projects/flink/KMeans.java

@@ -38,40 +38,84 @@ public class KMeans {
         final Integer maxIterations = params.getInt("maxIterations", 25);
 
         // Read CSV input
-        DataSet<Tuple1<Double>> csvInput = env.readCsvFile(params.get("input")).types(Double.class);
+        DataSet<Tuple2<Double, Double>> inputCsv = env.readCsvFile(params.get("input")).types(Double.class, Double.class);
 
-        // Convert CSV to internal format
-        DataSet<Double> input = csvInput
-            .map(point -> point.f0);
+        // Convert to internal format
+        DataSet<Point> input = inputCsv
+            .map(tuple -> new Point(tuple.f0, tuple.f1));
 
         // Generate random centroids
         final RandomCentroids r = new RandomCentroids(k);
-        IterativeDataSet<Double> centroids = env.fromCollection(r, Double.class).iterate(maxIterations);
+        IterativeDataSet<Point> centroids = env.fromCollection(r, Point.class).iterate(maxIterations);
 
         // Assign points to centroids
-        DataSet<Tuple2<Double, Integer>> assigned = input
+        DataSet<Tuple2<Point, Integer>> assigned = input
             .map(new AssignCentroid()).withBroadcastSet(centroids, "centroids");
 
         // Calculate means
-        DataSet<Double> newCentroids = assigned
+        DataSet<Point> newCentroids = assigned
             .map(new MeanPrepare())
             .groupBy(1) // GroupBy CentroidID
             .reduce(new MeanSum())
             .map(new MeanDivide());
 
-        DataSet<Double> finalCentroids = centroids.closeWith(newCentroids);
+        DataSet<Point> finalCentroids = centroids.closeWith(newCentroids);
 
         // Final assignment of points to centroids
         assigned = input
             .map(new AssignCentroid()).withBroadcastSet(finalCentroids, "centroids");
 
-        assigned.writeAsCsv(params.get("output", "output.csv"));
+        // Convert to external format
+        DataSet<Tuple3<Double, Double, Integer>> output = assigned
+            .map(new MapFunction<Tuple2<Point, Integer>, Tuple3<Double, Double, Integer>>() {
+                @Override
+                public Tuple3<Double, Double, Integer> map(Tuple2<Point, Integer> tuple) {
+                    return new Tuple3<Double, Double, Integer>(tuple.f0.x, tuple.f0.y, tuple.f1);
+                }
+            });
+
+        output.writeAsCsv(params.get("output", "output.csv"));
 
         env.execute("K-Means clustering");
     }
 
+    public static class Point implements Comparable<Point> {
+        public Double x;
+        public Double y;
 
-    public static class RandomCentroids implements Iterator<Double>, Serializable {
+        public Point(Double x, Double y) {
+            this.x = x;
+            this.y = y;
+        }
+
+        public int compareTo(Point other) {
+            int comp = x.compareTo(other.x);
+            if (comp == 0) {
+                comp = y.compareTo(other.y);
+            }
+            return comp;
+        }
+
+        public Point addTo(Point other) {
+            // Since input is always re-fetched we can overwrite the values
+            x += other.x;
+            y += other.y;
+            return this;
+        }
+
+        public Point divideBy(Integer factor) {
+            x /= factor;
+            y /= factor;
+            return this;
+        }
+
+        public Double distanceTo(Point other) {
+            return Math.sqrt(Math.pow(other.x - x, 2) + Math.pow(other.y - y, 2));
+        }
+
+    }
+
+    public static class RandomCentroids implements Iterator<Point>, Serializable {
 
         Integer k;
         Integer i;
@@ -89,9 +133,9 @@ public class KMeans {
         }
 
         @Override
-        public Double next() {
+        public Point next() {
             i += 1;
-            return r.nextDouble();
+            return new Point(r.nextDouble(), r.nextDouble());
         }
 
         private void readObject(ObjectInputStream inputStream) throws ClassNotFoundException, IOException {
@@ -102,9 +146,9 @@ public class KMeans {
         }
     }
 
-    public static class AssignCentroid extends RichMapFunction<Double, Tuple2<Double, Integer>> {
+    public static class AssignCentroid extends RichMapFunction<Point, Tuple2<Point, Integer>> {
         // Point → Point, CentroidID
-        private List<Double> centroids;
+        private List<Point> centroids;
 
         @Override
         public void open(Configuration parameters) throws Exception {
@@ -113,56 +157,48 @@ public class KMeans {
         }
 
         @Override
-        public Tuple2<Double, Integer> map(Double point) {
+        public Tuple2<Point, Integer> map(Point point) {
             Integer c;
-            Double centroid;
+            Point centroid;
             Double distance;
             Integer minCentroid = 4;
             Double minDistance = Double.POSITIVE_INFINITY;
 
             for (c = 0; c < centroids.size(); c++) {
                 centroid = centroids.get(c);
-                distance = distancePointCentroid(point, centroid);
+                distance = point.distanceTo(centroid);
                 if (distance < minDistance) {
                     minCentroid = c;
                     minDistance = distance;
                 }
             }
 
-            return new Tuple2<Double, Integer>(point, minCentroid);
+            return new Tuple2<Point, Integer>(point, minCentroid);
         }
 
-        private Double distancePointCentroid(Double point, Double centroid) {
-            return Math.abs(point - centroid);
-            // return Math.sqrt(Math.pow(point, 2) + Math.pow(centroid, 2));
-        }
     }
 
-    public static class MeanPrepare implements MapFunction<Tuple2<Double, Integer>, Tuple3<Double, Integer, Integer>> {
+    public static class MeanPrepare implements MapFunction<Tuple2<Point, Integer>, Tuple3<Point, Integer, Integer>> {
         // Point, CentroidID → Point, CentroidID, Number of points
         @Override
-        public Tuple3<Double, Integer, Integer> map(Tuple2<Double, Integer> point) {
-            return new Tuple3<Double, Integer, Integer>(point.f0, point.f1, 1);
+        public Tuple3<Point, Integer, Integer> map(Tuple2<Point, Integer> info) {
+            return new Tuple3<Point, Integer, Integer>(info.f0, info.f1, 1);
         }
     }
 
-    public static class MeanSum implements ReduceFunction<Tuple3<Double, Integer, Integer>> {
+    public static class MeanSum implements ReduceFunction<Tuple3<Point, Integer, Integer>> {
         // Point, CentroidID (irrelevant), Number of points
         @Override
-        public Tuple3<Double, Integer, Integer> reduce(Tuple3<Double, Integer, Integer> a, Tuple3<Double, Integer, Integer> b) {
-            return new Tuple3<Double, Integer, Integer>(sumPoints(a.f0, b.f0), a.f1, a.f2 + b.f2);
-        }
-
-        private Double sumPoints(Double a, Double b) {
-            return a + b;
+        public Tuple3<Point, Integer, Integer> reduce(Tuple3<Point, Integer, Integer> a, Tuple3<Point, Integer, Integer> b) {
+            return new Tuple3<Point, Integer, Integer>(a.f0.addTo(b.f0), a.f1, a.f2 + b.f2);
         }
     }
 
-    public static class MeanDivide implements MapFunction<Tuple3<Double, Integer, Integer>, Double> {
+    public static class MeanDivide implements MapFunction<Tuple3<Point, Integer, Integer>, Point> {
         // Point, CentroidID (irrelevant), Number of points → Point
         @Override
-        public Double map(Tuple3<Double, Integer, Integer> point) {
-            return point.f0 / point.f2;
+        public Point map(Tuple3<Point, Integer, Integer> info) {
+            return info.f0.divideBy(info.f2);
         }
     }