view gnv-artifacts/src/main/java/de/intevation/gnv/math/Interpolation2D.java @ 504:efab67e68bba

Trigger the calculation of the "Horizontalschnitt" when the output state is initialized. gnv-artifacts/trunk@587 c6561f87-3c4e-4783-a992-168aeb5c3f6f
author Sascha L. Teichmann <sascha.teichmann@intevation.de>
date Wed, 20 Jan 2010 16:05:52 +0000
parents 70adafe2b9d5
children d9d933e06875
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line source
package de.intevation.gnv.math;

import com.vividsolutions.jts.geom.Coordinate;
import com.vividsolutions.jts.geom.Envelope;

import com.vividsolutions.jts.index.quadtree.Quadtree;

import gnu.trove.TDoubleArrayList;

import java.util.ArrayList;
import java.util.Collections;
import java.util.HashMap;
import java.util.List;

import org.apache.commons.math.stat.descriptive.moment.Mean;
import org.apache.commons.math.stat.descriptive.moment.StandardDeviation;

import org.apache.log4j.Logger;

/**
 *  @author Sascha L. Teichmann (sascha.teichmann@intevation.de)
 */
public final class Interpolation2D
{
    private static Logger log = Logger.getLogger(Interpolation2D.class);

    public interface Consumer {
        void interpolated(Coordinate point, boolean success);
    } // interface Consumer

    private Interpolation2D() {
    }

    private static final double dist(double a, double b) {
        a -= b;
        return Math.sqrt(a*a);
    }

    private static final double OUTLIER_EPS = 0.4d;

    public static final double [] calculateBufferRemoveOutlier(
        List <? extends Point2d> points
    ) {
        HashMap<Integer, ArrayList<Point2d>> iMap = 
            new HashMap<Integer, ArrayList<Point2d>>();

        HashMap<Integer, ArrayList<Point2d>> jMap = 
            new HashMap<Integer, ArrayList<Point2d>>();

        for (int k = points.size()-1; k >= 0; --k) {
            Point2d p = points.get(k);

            ArrayList<Point2d> jList = jMap.get(p.j);
            ArrayList<Point2d> iList = iMap.get(p.i);

            if (jList == null) {
                jMap.put(p.j, jList = new ArrayList<Point2d>());
            }
            jList.add(p);

            if (iList == null) {
                iMap.put(p.i, iList = new ArrayList<Point2d>());
            }
            iList.add(p);
        }

        TDoubleArrayList deltas = new TDoubleArrayList();

        Mean mean            = new Mean();
        StandardDeviation sd = new StandardDeviation();

        for (ArrayList<Point2d> v: jMap.values()) {
            Collections.sort(v, Point2d.Y_COMPARATOR);
            for (int i = 1, L = v.size(); i < L; ++i) {
                double dy = Math.abs(v.get(i).y - v.get(i-1).y);
                deltas.add(dy);
                mean.increment(dy);
                sd  .increment(dy);
            }
        }

        deltas.sort();

        double m   = mean.getResult();
        double s   = sd  .getResult();
        double eps = OUTLIER_EPS*s;

        int yi = deltas.size() - 1;
        while (yi > 0 && dist(deltas.get(yi), m) > eps) {
            --yi;
        }

        double dyMax = deltas.get(yi) + 1e-5d;

        if (log.isDebugEnabled()) {
            log.debug("mean  y: " + m);
            log.debug("sigma y: " + s);
        }

        deltas.reset();
        mean.clear();
        sd  .clear();

        for (ArrayList<Point2d> v: iMap.values()) {
            Collections.sort(v, Point2d.X_COMPARATOR);
            for (int i = 1, L = v.size(); i < L; ++i) {
                double dx = Math.abs(v.get(i).x - v.get(i-1).x);
                deltas.add(dx);
                mean.increment(dx);
                sd  .increment(dx);
            }
        }

        deltas.sort();

        m   = mean.getResult();
        s   = sd  .getResult();
        eps = OUTLIER_EPS*s;

        int xi = deltas.size() - 1;

        while (xi > 0 && dist(deltas.get(xi), m) > eps) {
            --xi;
        }

        double dxMax = deltas.get(xi) + 1e-5d;

        if (log.isDebugEnabled()) {
            log.debug("mean  y: " + m);
            log.debug("sigma y: " + s);
        }

        return new double [] { dxMax, dyMax };
    }

    public static final double [] calculateBuffer(
        List <? extends Point2d> points
    ) {
        HashMap<Integer, ArrayList<Point2d>> iMap = 
            new HashMap<Integer, ArrayList<Point2d>>();

        HashMap<Integer, ArrayList<Point2d>> jMap = 
            new HashMap<Integer, ArrayList<Point2d>>();

        for (int k = points.size()-1; k >= 0; --k) {
            Point2d p = points.get(k);

            ArrayList<Point2d> jList = jMap.get(p.j);
            ArrayList<Point2d> iList = iMap.get(p.i);

            if (jList == null) {
                jMap.put(p.j, jList = new ArrayList<Point2d>());
            }
            jList.add(p);

            if (iList == null) {
                iMap.put(p.i, iList = new ArrayList<Point2d>());
            }
            iList.add(p);
        }

        double dxMax = -Double.MAX_VALUE;
        double dyMax = -Double.MAX_VALUE;

        for (ArrayList<Point2d> v: jMap.values()) {
            Collections.sort(v, Point2d.Y_COMPARATOR);
            for (int i = 1, L = v.size(); i < L; ++i) {
                double dy = Math.abs(v.get(i).y - v.get(i-1).y);
                if (dy > dyMax) {
                    dyMax = dy;
                }
            }
        }

        dyMax += 1e-5d;

        for (ArrayList<Point2d> v: iMap.values()) {
            Collections.sort(v, Point2d.X_COMPARATOR);
            for (int i = 1, L = v.size(); i < L; ++i) {
                double dx = Math.abs(v.get(i).x - v.get(i-1).x);
                if (dx > dxMax) {
                    dxMax = dx;
                }
            }
        }

        dxMax += 1e-5d;

        return new double [] { dxMax, dyMax };
    }

    public static void interpolate(
        List<? extends Coordinate> path,
        List<? extends Point2d>    points,
        double                     from,
        double                     to,
        int                        steps,
        Metrics                    metrics,
        Consumer                   consumer
    ) {
        boolean debug = log.isDebugEnabled();

        int N = path.size();
        int M = points.size();

        if (debug) {
            log.debug("Size of path: " + N);
            log.debug("Size of points: " + M);
        }

        if (M < 1 || N < 2) { // nothing to do
            return;
        }

        double [] buffer = calculateBuffer(points);
        double dxMax = buffer[0];
        double dyMax = buffer[1];

        if (debug) {
            log.debug("buffer size: " + dxMax + " / " + dyMax);
        }

        // put into spatial index to speed up finding neighbors.
        Quadtree spatialIndex = new Quadtree();

        for (int i = 0; i < M; ++i) {
            Point2d p = points.get(i);
            spatialIndex.insert(p.envelope(), p);
        }

        LinearToMap linearToMap = new LinearToMap(
            path, from, to, metrics);

        double dP = (to - from)/steps;

        Coordinate center = new Coordinate();

        Envelope queryBuffer = new Envelope();

        Point2d [] neighbors = new Point2d[4];

        int missedInterpolations = 0;
        int interpolations = 0;

        L1Comparator invL1 = new L1Comparator(center);

        for (double p = from; p <= to; p += dP) {
            if (!linearToMap.locate(p, center)) {
                continue;
            }
            queryBuffer.init(
                center.x - dxMax, center.x + dxMax, 
                center.y - dyMax, center.y + dyMax);

            List potential = spatialIndex.query(queryBuffer);

            Collections.sort(potential, invL1);

            neighbors[0] = neighbors[1] = 
            neighbors[2] = neighbors[3] = null;

            /* bit code of neighbors
               0---1
               | x |
               2---3
            */

            int mask = 0;
            // reversed order is essential here!
            for (int i = potential.size()-1; i >= 0; --i) {
                Point2d n = (Point2d)potential.get(i);
                int code = n.x > center.x ? 1 : 0;
                if (n.y > center.y) code |= 2;
                neighbors[code] = n;
                mask |= 1 << code;
            }

            int numNeighbors = Integer.bitCount(mask);

            // only interpolate if we have all four neighbors
            // and we do not have any gaps.
            if (numNeighbors == 4
            && !neighbors[0].hasIGap(neighbors[1])
            && !neighbors[1].hasJGap(neighbors[3])
            && !neighbors[3].hasIGap(neighbors[2])
            && !neighbors[2].hasJGap(neighbors[0])
            ) {
                double z1 = interpolate(
                    neighbors[0].x, neighbors[0].z,
                    neighbors[1].x, neighbors[1].z,
                    center.x);
                double z2 = interpolate(
                    neighbors[2].x, neighbors[2].z,
                    neighbors[3].x, neighbors[3].z,
                    center.x);
                double y1 = interpolate(
                    neighbors[0].x, neighbors[0].y,
                    neighbors[1].x, neighbors[1].y,
                    center.x);
                double y2 = interpolate(
                    neighbors[2].x, neighbors[2].y,
                    neighbors[3].x, neighbors[3].y,
                    center.x);
                center.z = interpolate(
                    y1, z1,
                    y2, z2,
                    center.y);
                consumer.interpolated(center, true);
                ++interpolations;
            }
            else {
                consumer.interpolated(center, false);
                ++missedInterpolations;
            }
        }

        if (debug) {
            log.debug("interpolations: " + 
                interpolations + " / " + missedInterpolations);
        }
    }

    public static final double interpolate(
        double x1, double y1,
        double x2, double y2,
        double x
    ) {
        if (x2 == x1) {
            return (y1 + y2)*0.5d;
        }
        double m = (y2-y1)/(x2-x1);
        double b = y1 - m*x1;
        return m*x + b;
    }
}
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