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mojays |
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package appl.parallel.spmd.split; |
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import java.awt.Point; |
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import java.awt.Rectangle; |
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import java.util.Vector; |
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alfonx |
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import schmitzm.data.WritableGrid; |
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mojays |
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import appl.parallel.util.Helper; |
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/** |
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* Responsible for splitting a 2D Area (e.g a {@link WritableGrid}) in a 2D |
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* fashion. The splitting is irregular, meaning that the rectangles are not |
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* equally sized, but partitioned according to the given weights. |
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* Splitting is as follows: <br><br> |
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* 1 to 4 Partitions: 1 row <br> |
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* 4 to 8 Partitions: 2 rows <br> |
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* 9 to 15 Partitions: 3 rows <br> |
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* and so on (depending on the square root of the partititons)<br> |
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* <br> |
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* For partitioning the this class strongly depends on {@link SplitMap1DHorizontal} |
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* and {@link SplitMap1DVertical}. First the squareroot of the number of |
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* participating resources is taken to determine how many rows should be |
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* created. After this the height of the rows is weighted by adding the weight |
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* of the resources in that horizontal partition. The Grid is then splitted |
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* horizontal. Finally the horizontal partitions are splitted vertical according |
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* to the relative weight to each other. This is only a a virtual split (a map |
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* of a split). <br> |
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* A neighborhood range can be specified to create partitions that overlap each |
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* other. This overlapping can be done in two different ways: <br> |
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* <br> |
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* <b>Inboxing</b>(default):<br> |
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* <br> |
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* Inboxing means, that the neighborhood area is not part of the calculation |
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* area. <br> |
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* <br> |
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* <b>Outboxing:</b><br> |
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* Outboxing means that the neighborhood area is part of the calculation area. |
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* <br> |
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* <br> |
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* Note that this may also be applied to three dimensional data structures (a 2D |
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* splitting of a 3D datatype). |
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* |
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* @author Dominik Appl |
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*/ |
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public class SplitMap2D extends AbstractSplitMap implements SplitMap { |
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private SplitMap1DHorizontal horizontalMap; |
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private SplitMap1DVertical[] verticalMaps; |
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public SplitMap2D(int width, int height, int neighborhoodRange, |
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int noOfPartitions, NeighborhoodBoxingMode boxingMode) { |
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super(width, height, neighborhoodRange, noOfPartitions, boxingMode); |
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} |
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/** |
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* needed for serialization |
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*/ |
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public SplitMap2D() { |
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} |
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/* |
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* (non-Javadoc) |
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* |
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* @see appl.parallel.spmd.split.AbstractSplitMap#makeMap() |
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*/ |
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public void makeMap() { |
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// take the squareroot of the number of participating resources to |
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// determine the number of rows: |
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int noOfRows = (int) Math.sqrt(noOfPartitions); |
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// calculate weights for the rows (sum of the weights of the partitions |
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// inside that row) |
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double rowWeights[] = new double[noOfRows]; |
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int noOfCols[] = new int[noOfRows]; // noOfCols per row |
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for (int row = 0; row < noOfRows; row++) { |
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// calculate no. of cols in the row: |
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noOfCols[row] = (noOfPartitions / noOfRows); |
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// the last row may contain a greater number of cols |
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if (row == noOfRows - 1) |
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noOfCols[row] = noOfPartitions |
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- ((noOfRows - 1) * noOfCols[row]); |
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for (int col = 0; col < noOfCols[row]; col++) |
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rowWeights[row] += weights[row * col + col]; |
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} |
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// create the horizontal Splitmap |
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horizontalMap = new SplitMap1DHorizontal(globalWidth, globalHeight, |
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neighborhoodRange, noOfRows, boxingMode); |
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horizontalMap.setWeights(rowWeights); |
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horizontalMap.makeMap(); |
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// for each horizontal partition create a vertical split |
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verticalMaps = new SplitMap1DVertical[noOfRows]; |
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for (int row = 0; row < noOfRows; row++) { |
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//notice: all splitmaps start at (0,0), later a conversion must be made |
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verticalMaps[row] = new SplitMap1DVertical((int) horizontalMap |
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.getGlobalBounds().getWidth(), (int) horizontalMap |
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.getPartitionCalculationBounds(row).getHeight(), neighborhoodRange, |
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noOfCols[row], boxingMode); |
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int ratings[] = new int[noOfCols[row]]; |
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for (int col = 0; col < noOfCols[row]; col++) { |
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{ |
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// the rating of the col is the weight of the col * 100000 |
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// (ratings must be positive integers) |
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ratings[col] = (int) (weights[row * col + col] * 1000000); |
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} |
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verticalMaps[row].setWeights(Helper.calculateWeights(ratings)); |
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verticalMaps[row].makeMap(); |
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} |
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} |
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// now we have partitioned the grid. Lets assign the calculation and |
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// neighborhoodareas: |
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for (int i = 0; i < noOfPartitions; i++) { |
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int row = getRowForIdx(i); |
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int col = getColForIdx(i); |
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partitionCalculationBounds[i] = verticalMaps[row] |
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.getPartitionCalculationBounds(col); |
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//because all splitmaps start with (0,0) we must move |
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//the rectangles to the right position |
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int x = (int) partitionCalculationBounds[i].getX(); //the x value remains unchanged |
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partitionCalculationBounds[i].setLocation( |
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new Point(x,(int) horizontalMap.getPartitionCalculationBounds(row).getY())); |
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// if there is only one partition there are no explicit neighborhood |
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// bounds |
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if (noOfPartitions == 1) |
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partitionNeighborhoodBounds[i] = partitionCalculationBounds[i]; |
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// else simply extend the Rectangle with the Neighborhoodbounds |
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// created calculation Area (@see AbstractSplitMap) |
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else |
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partitionNeighborhoodBounds[i] = new Rectangle( |
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(int) partitionCalculationBounds[i].getX() |
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- neighborhoodRange, |
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(int) partitionCalculationBounds[i].getY() |
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- neighborhoodRange, |
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(int) (partitionCalculationBounds[i].getWidth() + 2 * neighborhoodRange), |
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(int) (partitionCalculationBounds[i].getHeight() + 2 * neighborhoodRange)); |
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// cut of the obverlapping sections which are out of the grid: |
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partitionNeighborhoodBounds[i] = partitionNeighborhoodBounds[i] |
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.intersection(globalBounds); |
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// the partitionCalculation bounds were created for inboxing: |
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if (boxingMode == NeighborhoodBoxingMode.outBoxing) |
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partitionCalculationBounds[i] = partitionNeighborhoodBounds[i]; |
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} |
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} |
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/** |
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* @param i |
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* @return |
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*/ |
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private int getColForIdx(int index) { |
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int noOfRows = (int) Math.sqrt(noOfPartitions); |
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int avgNoOfCols = noOfPartitions / noOfRows; |
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int currentRow = getRowForIdx(index); |
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int returnValue = (index - currentRow*avgNoOfCols); |
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return returnValue; |
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} |
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private int getRowForIdx(int index) { |
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int noOfRows = (int) Math.sqrt(noOfPartitions); |
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int avgNoOfCols = noOfPartitions / noOfRows; |
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int returnValue = index / avgNoOfCols; |
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//special handling for the last row (contains more partitions) |
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if(noOfRows==returnValue) |
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return noOfRows-1; |
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else return returnValue; |
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} |
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/* |
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* (non-Javadoc) |
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* |
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* @see appl.parallel.spmd.split.SplitMap#getNeighborsForPosition(int) |
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*/ |
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public int[] getNeighborsForPosition(int pos) { |
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Vector neighbors = new Vector(); |
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// simply intersect with all partitions to find the neighbors: |
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for (int i = 0; i < noOfPartitions; i++) { |
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if (i == pos) |
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continue; |
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if (partitionNeighborhoodBounds[i] |
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.intersects(partitionNeighborhoodBounds[pos])) |
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neighbors.add(pos); |
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} |
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int results[] = new int[neighbors.size()]; |
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// copy into array |
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for (int i = 0; i < results.length; i++) { |
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results[i] = (Integer) neighbors.get(i); |
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} |
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return results; |
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} |
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/* |
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* (non-Javadoc) |
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* |
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* @see appl.parallel.spmd.split.AbstractSplitMap#getDescription() |
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*/ |
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@Override |
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public String getDescription() { |
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return "2D-irregular Splitmap"; |
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} |
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} |