207 lines
7.8 KiB
Java
207 lines
7.8 KiB
Java
package org.gcube.dataanalysis.geo.utils;
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import java.util.ArrayList;
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import java.util.List;
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import org.gcube.contentmanagement.lexicalmatcher.utils.AnalysisLogger;
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import org.gcube.dataanalysis.ecoengine.utils.Tuple;
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import ucar.ma2.ArrayByte;
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import ucar.ma2.ArrayDouble;
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import ucar.ma2.IndexIterator;
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public class VectorOperations {
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public static ArrayDouble.D2 arrayByte2DArrayDouble(ArrayByte bytes) {
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int[] shapeD = bytes.getShape();
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int yD = shapeD[0];
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int xD = shapeD[1];
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AnalysisLogger.getLogger().debug(xD + "X" + yD + "=" + (xD * yD));
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ArrayDouble.D2 doublea = new ArrayDouble.D2(yD, xD);
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IndexIterator iterator = bytes.getIndexIterator();
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for (int x = 0; x < xD; x++) {
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for (int y = 0; y < yD; y++) {
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Byte bytex = (Byte) iterator.next();
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doublea.set(y, x, bytex.doubleValue());
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}
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}
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return doublea;
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}
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public static ArrayDouble.D3 arrayByte3DArrayDouble(ArrayByte bytes) {
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int[] shapeD = bytes.getShape();
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int zD = shapeD[0];
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int yD = shapeD[1];
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int xD = shapeD[2];
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AnalysisLogger.getLogger().debug(xD + "X" + yD + "X" + zD + "=" + (xD * yD * zD));
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ArrayDouble.D3 doublea = new ArrayDouble.D3(zD, yD, xD);
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IndexIterator iterator = bytes.getIndexIterator();
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for (int x = 0; x < xD; x++) {
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for (int y = 0; y < yD; y++) {
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for (int z = 0; z < zD; z++) {
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Byte bytex = (Byte) iterator.next();
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doublea.set(z, y, x, bytex.doubleValue());
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}
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}
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}
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return doublea;
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}
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/**
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* Finds the best association between a grid of 3d points in a certain time instant and a set of 5 dimensional points. each tuple is expected to be formed by (x,y,z,t,value) in 5 dimensions and by (x,y,z) in 3 dimensions
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**/
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// suggestion: given a resolution R, give Math.sqrt(2)*R/2=0.7*R as tolerance
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public static List<Double> assignPointsValuesToGrid(List<Tuple<Double>> grid3d, int gridTimeInstant, List<Tuple<Double>> coordinates5d, double tolerance) {
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List<Double> valuesForGrid = new ArrayList<Double>();
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int gridSize = grid3d.size();
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for (int i = 0; i < gridSize; i++) {
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valuesForGrid.add(Double.NaN);
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}
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// AnalysisLogger.getLogger().debug("Grid contains: "+grid3d.size()+" values");
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// AnalysisLogger.getLogger().debug("Dataset contains: "+coordinates5d.size()+" values");
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int foundmatches = 0;
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for (Tuple<Double> coord5d : coordinates5d) {
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double rx = coord5d.getElements().get(0);
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double ry = coord5d.getElements().get(1);
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double rz = coord5d.getElements().get(2);
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double rt = coord5d.getElements().get(3);
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double rvalue = coord5d.getElements().get(4);
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int gridIdx = 0;
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for (Tuple<Double> coord3d : grid3d) {
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double x = coord3d.getElements().get(0);
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double y = coord3d.getElements().get(1);
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double z = coord3d.getElements().get(2);
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double d = distance(x, y, z, gridTimeInstant, rx, ry, rz, rt);
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if (d <= tolerance) {
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// AnalysisLogger.getLogger().debug("Association: distance between grid:("+x+","+y+","+z+","+gridTimeInstant+") and point:("+rx+","+ry+","+rz+","+rt+") is "+d);
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valuesForGrid.set(gridIdx, rvalue);
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foundmatches++;
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}
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gridIdx++;
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}
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}
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AnalysisLogger.getLogger().debug("Association: Found "+foundmatches+" matches between the grid of points and the coordinates");
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return valuesForGrid;
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}
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public static List<Double> assignGridValuesToPoints2D(List<Tuple<Double>> grid3d, List<Double> gridValues, List<Tuple<Double>> coordinates4d, double tolerance) {
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List<Double> valuesForPoints = new ArrayList<Double>();
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int gridSize = coordinates4d.size();
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for (int i = 0; i < gridSize; i++) {
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valuesForPoints.add(Double.NaN);
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}
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int foundmatches = 0;
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int points=0;
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for (Tuple<Double> coord4d : coordinates4d) {
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double rx = coord4d.getElements().get(0);
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double ry = coord4d.getElements().get(1);
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int gridIdx = 0;
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for (Tuple<Double> gridElement : grid3d) {
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double x = gridElement.getElements().get(0);
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double y = gridElement.getElements().get(1);
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double d = distance(x, y, 0, 0, rx, ry, 0, 0);
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if (d <= tolerance) {
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// AnalysisLogger.getLogger().debug("Association: distance between grid:("+x+","+y+","+z+","+gridTimeInstant+") and point:("+rx+","+ry+","+rz+","+rt+") is "+d);
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valuesForPoints.set(points, gridValues.get(gridIdx));
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foundmatches++;
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break;
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}
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gridIdx++;
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}
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points++;
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}
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AnalysisLogger.getLogger().debug("Association: Found "+foundmatches+" matches between the points and the grid");
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return valuesForPoints;
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}
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public static List<Double> assignGridValuesToPoints(List<Tuple<Double>> grid3d, int gridTimeInstant, List<Double> gridValues, List<Tuple<Double>> coordinates4d, double tolerance) {
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List<Double> valuesForPoints = new ArrayList<Double>();
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int gridSize = coordinates4d.size();
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for (int i = 0; i < gridSize; i++) {
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valuesForPoints.add(Double.NaN);
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}
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int foundmatches = 0;
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int points=0;
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for (Tuple<Double> coord4d : coordinates4d) {
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double rx = coord4d.getElements().get(0);
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double ry = coord4d.getElements().get(1);
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double rz = coord4d.getElements().get(2);
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double rt = coord4d.getElements().get(3);
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int gridIdx = 0;
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for (Tuple<Double> gridElement : grid3d) {
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double x = gridElement.getElements().get(0);
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double y = gridElement.getElements().get(1);
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double z = gridElement.getElements().get(2);
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double d = distance(x, y, z, gridTimeInstant, rx, ry, rz, rt);
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if (d <= tolerance) {
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// AnalysisLogger.getLogger().debug("Association: distance between grid:("+x+","+y+","+z+","+gridTimeInstant+") and point:("+rx+","+ry+","+rz+","+rt+") is "+d);
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valuesForPoints.set(points, gridValues.get(gridIdx));
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foundmatches++;
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break;
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}
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gridIdx++;
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}
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points++;
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}
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AnalysisLogger.getLogger().debug("Association: Found "+foundmatches+" matches between the points and the grid");
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return valuesForPoints;
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}
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public static double distance(double x1, double y1, double z1, double t1, double x2, double y2, double z2, double t2) {
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return Math.sqrt(((x1 - x2) * (x1 - x2)) + ((y1 - y2) * (y1 - y2)) + ((z1 - z2) * (z1 - z2)) + ((t1 - t2) * (t1 - t2)));
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}
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public static List<Tuple<Double>> generateCoordinateTripletsInBoundingBox(double x1, double x2, double y1, double y2, double z, double xResolution, double yResolution) {
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int ysteps = (int) ((y2 - y1) / yResolution);
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int xsteps = (int) ((x2 - x1) / xResolution);
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List<Tuple<Double>> tuples = new ArrayList<Tuple<Double>>();
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AnalysisLogger.getLogger().debug("Building the points grid according to YRes:" + yResolution + " and XRes:" + xResolution);
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// build the tuples according to the desired resolution
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for (int i = 0; i < ysteps + 1; i++) {
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double y = (i * yResolution) + y1;
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if (i == ysteps)
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y = y2;
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for (int j = 0; j < xsteps + 1; j++) {
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double x = (j * xResolution) + x1;
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if (j == xsteps)
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x = x2;
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tuples.add(new Tuple<Double>(x, y, z));
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}
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}
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return tuples;
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}
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public void applyNearestNeighbor() {
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/*
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* AnalysisLogger.getLogger().debug("Applying nearest Neighbor to all the rows"); //apply nearest neighbor to each row AlgorithmConfiguration config = new AlgorithmConfiguration(); config.setConfigPath(configDir); boolean rapidinit = false;
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*
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*
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* for (int i=0;i<slice.length;i++){ // AnalysisLogger.getLogger().debug("Checking for unfilled values"); boolean tofill = false; for (int j=0;j<slice[i].length;j++) { if (new Double(slice[i][j]).equals(Double.NaN)) tofill = true; } if (tofill){ if (!rapidinit){ config.initRapidMiner(); rapidinit=true; } AnalysisLogger.getLogger().debug("Filling signal"); double[] ssliced = SignalProcessing.fillSignal(slice[i]); slice[i] = ssliced; } // else // AnalysisLogger.getLogger().debug("Signal yet complete"); }
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*/
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}
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}
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